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1
MOLECULAR AND GENETIC DETERMINATION OF THE ROLE OF ELSINOCHROME TOXINS PRODUCED BY Elsinoë fawcettii CAUSING CITRUS SCAB
By
HUI-LING LIAO
A DISSERTATION PRESENTED TO THE GRADUATE SCHOOL OF THE UNIVERSITY OF FLORIDA IN PARTIAL FULFILLMENT
OF THE REQUIREMENTS FOR THE DEGREE OF DOCTOR OF PHILOSOPHY
UNIVERSITY OF FLORIDA
2008
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© 2008 Hui-Ling Liao
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To my grandmother, Ma-Men Liao, who always supports my educational pursuits
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ACKNOWLEDGMENTS
I am grateful to several individuals who have helped me towards my education.
I would like to thank my advisor, Dr. Kuang-Ren Chung, for his wise guidance towards
my accomplishment. The excellent projects and the brilliant suggestions he gave sparked my
interest in research to a great extent.
Many thanks to all my supervisory committee members, Dr. Jacqueline Burns, Dr. James
Graham, and Dr. Jeffrey Rollins, for their sage counsel and help throughout my studies and
dissertation process.
A very sincere and warm gratitude goes to all my lovely friends that I have made in
Gainesville and CREC. Their love is the key factor supporting me over the past four years when
my family is million of miles away from me. A special thanks to my roommate, Karthik, who
took care of me like his family.
I thank my father- and mother-in-law for taking care of my lovely daughter, Chin-Chin, so
that I can be involved in research without being worried about anything. Much love and thanks
to my husband, Chih-Ming, for his constant support and encouragement.
Most importantly, I would like to give my heartfelt thanks to my grandma for the sacrifices
she has made to support me towards my education.
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TABLE OF CONTENTS page
ACKNOWLEDGMENTS ...............................................................................................................4
LIST OF TABLES...........................................................................................................................9
LIST OF FIGURES .......................................................................................................................10
ABSTRACT...................................................................................................................................13
CHAPTER
1 INTRODUCTION AND LITERATURE REVIEW ..............................................................15
Biology of Elsinoë fawcettii Causing Citrus Scab..................................................................15 Symptoms, Disease Cycles and Disease Control of Citrus Scab Caused by Elsinoë
fawcettii ...............................................................................................................................17 Symptoms ........................................................................................................................17 Disease Cycle ..................................................................................................................17 Disease Control ...............................................................................................................18
Secondary Metabolites of Fungi .............................................................................................19 Secondary Metabolites of Fungi......................................................................................19 Elsinochromes Produced by Elsinoë fawcettii ................................................................20 Polyketide Biosynthesis...................................................................................................21 Gene Clusters...................................................................................................................24
Research Overview.................................................................................................................25
2 CELLULAR TOXICITY OF ELSINOCHROME PHYTOTOXINS PRODUCED BY Elsinoë fawcettii......................................................................................................................32
Introduction.............................................................................................................................33 Materials and Methods ...........................................................................................................34
Biological Materials and Cultural Conditions.................................................................34 Isolation and Analysis of the Red/Orange Pigments.......................................................35 Toxicity Assays to Plant Cells.........................................................................................36 Detection of Singlet Oxygen and Superoxide Ions .........................................................37 Determination of Electrolyte Leakage.............................................................................38 Statistical Analysis ..........................................................................................................39
Results.....................................................................................................................................39 Isolation and Characterization of ESCs from Elsinoë fawcettii ......................................39 Toxicity of ESCs from E. fawcettii to Host and Non-Host Cells ....................................40 Antioxidants Reduce ESC Toxicity.................................................................................40 ESCs are Toxic to Citrus Leaves.....................................................................................41 Production of Reactive Oxygen Species by ESCs ..........................................................41 Electrolyte Leakage Induced by ESCs ............................................................................42
Discussion...............................................................................................................................43
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3 ENVIRONMENTAL FACTORS AFFECTING PRODUCTION OF ELSINOCHROMES BY Elsinoë fawcettii ............................................................................58
Introduction.............................................................................................................................58 Materials and Methods ...........................................................................................................60
Fungal Strains, Maintenance, and Culture Conditions ....................................................60 ESC Purification and Quantification ...............................................................................61 Statistical Analysis ..........................................................................................................61 Preparation of Chemicals ................................................................................................61
Results and Discussion ...........................................................................................................62 Fungal Growth and ESC Production in Response to Light, Media Components and
pH.................................................................................................................................62 Carbon Sources on Fungal Growth and ESC Production................................................63 Effects of Inorganic and Organic Nitrogen on Fungal Growth and ESC Production .....63 Effects of Antioxidants on Fungal Growth and ESC Production....................................64 Effects of Ions on ESC Production..................................................................................64 Co-culturing Enhances ESC Production .........................................................................65
4 GENETIC DISSECTION DEFINES THE ROLES OF ELSINOCHROME PHYTOTOXIN FOR FUNGAL PATHOGENESIS AND CONIDIATION OF THE CITRUS PATHOGEN Elsinoë fawcettii................................................................................74
Introduction.............................................................................................................................74 Materials and Methods ...........................................................................................................76
Fungal Isolate and Growth Conditions............................................................................76 Extraction and Analysis of ESC Toxins..........................................................................77 Molecular Cloning and Analysis of the EfPKS1 Gene....................................................77 Targeted Gene Disruption ...............................................................................................78 Genetic Complementation ...............................................................................................79 Miscellaneous Methods of Processing Nucleic Acids.....................................................80 Preparation of Fungal Inoculum and Pathogenicity Assays............................................80
Results.....................................................................................................................................81 Cloning and Characterization of EfPKS1 Gene...............................................................81 Promoter Analysis of EfPKS1 Gene................................................................................82 Expression and Regulation of EfPKS1 Gene and ESC Production.................................82 EfPKS1 is Required for ESC Production.........................................................................83 Disruption of EfPKS1 Reduces Conidiation....................................................................85 The EfPKS1 Gene is Required for Full Virulence...........................................................85
Discussion...............................................................................................................................86
5 CHARACTERIZATION OF A GENE CLUSTER REQUIRED FOR THE BIOSYNTHESIS OF ELSINOCHROMES BY Elsinoë fawcettii .........................................99
Introduction...........................................................................................................................100 Materials and Methods .........................................................................................................101
Fungal Strains, Their Maintenance and Extraction/Analysis of ESC Toxin.................101 Chromosomal Walking and Sequence Analysis............................................................101
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Targeted Gene Disruption and Genetic Complementation ...........................................102 Molecular Techniques ...................................................................................................103 Conidia Production and Pathogenicity Assays..............................................................104 Nucleotide Sequences....................................................................................................104
Results...................................................................................................................................105 Sequence Analysis and Determination of Open Reading Frames (ORFs)....................105 Expression of Putative ORFs and ESC Accumulation..................................................106 Promoter Analysis for Identifying DNA Binding Motifs..............................................107 Targeted Disruption of the TSF1 Gene and Genetic Complementation........................108 Gene Regulation by TSF1 and Feedback Inhibition .....................................................110
Discussion.............................................................................................................................111
6 GENETIC AND PATHOLOGICAL DETERMINATIONS OF Elsinoë fawcettii FIELD ISOLATES FROM FLORIDA.............................................................................................128
Introduction...........................................................................................................................128 Materials and Methods .........................................................................................................130
Fungal Isolates and Growth Conditions ........................................................................130 Extraction and Analysis of Elsinochromes (ESCs) .......................................................130 Production and Germination of Conidia........................................................................131 Pathogenicity Assays.....................................................................................................131 Enzymatic Activity Assays............................................................................................132 PCR-Restriction Fragment Length Polymorphism (RFLP) and Sequence Analysis
of ITS and β-tubulin Genes........................................................................................133 Random Amplified Polymorphic DNA (RAPD) ..........................................................134 Miscellaneous Methods of Processing Nucleic Acids...................................................134
Results...................................................................................................................................135 Morphological Examination..........................................................................................135 Pathogenicity Assays.....................................................................................................135 Production of ESC Toxin in Culture .............................................................................136 Extraction of ESCs from Scab Lesions .........................................................................136 Further Characterization of a Nonpathogenic Elsinoë fawcettii Isolate ........................137 Alterations in Hydrolytic Enzyme Activities ................................................................137 Production of ESC and Expression of the EfPKS1 gene in the Nonpathogenic
Isolate (Ef41) .............................................................................................................138 Co-inoculation of Two E. fawcettii Isolates Reduces Lesion Formation......................138 Molecular Evaluation of E. fawcettii Isolates................................................................139
Discussion.............................................................................................................................140 APPENDIX
A SUPPLEMENTAL DATA FOR CHAPTER TWO.............................................................153
B SUPPLEMENTAL DATA FOR CHAPTER THREE .........................................................154
C SUPPLEMENTAL DATA FOR CHAPTER FOUR ...........................................................155
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D SUPPLEMENTAL DATA FOR CHAPTER SIX................................................................157
LIST OF REFERENCES.............................................................................................................162
BIOGRAPHICAL SKETCH .......................................................................................................175
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LIST OF TABLES Table page 3-1 Effects of ions and EGTA on ESC production by Elsinoë fawcettii .................................66
4-1 Conidial production in axenic cultures and pathogenicity assays on detached rough lemon leaves by inoculating with agar plugs cut from cultures of Elsinoë fawcettii wild type (WT), EfPKS1 null mutants (D1, D2, D3, and D4), and strains (C1 and C2) expressing a functional copy of EfPKS1............................................................................90
5-1 Elsinochrome (ESC) biosynthetic gene cluster and adjacent EfHP1-4 genes encoding hypothetical proteins in Elsinoë fawcettii ........................................................................117
5-2 Promoter analysis of genes in the elsinochrome (ESC) biosynthetic gene cluster of Elsinoë fawcettii...............................................................................................................119
6-1 Pathogenicity and production of elsinochromes (ESCs) in vivo and in planta by different field isolates of Elsinoë fawcettii ......................................................................143
6-2 Sequence identity (%) of fungal partial β-tubulin gene ...................................................145
B-1 Effects of ions on ESC production on CM by E. fawcettii ..............................................154
C-1 Sequences of primers .......................................................................................................155
D-1 Germination of Elsinoë fawcettii isolates on detached leaves of rough lemon and grapefruit..........................................................................................................................157
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LIST OF FIGURES Figure page 1-1 Symptoms of citrus scab caused by the pathogenic fungus, Elsinoë fawcettii ..................27
1-2 Life cycle of Elsinoë fawcettii, the causal agent of citrus scab. ........................................28
1-3 Structure of elsinochromes. ...............................................................................................29
1-4 Proposed model for the formation of activated oxygen species by photosensitizers ........30
1-5 Biosynthesis of fatty acid and polyketide in fungi.............................................................31
2-1 Thin-layer chromatography analysis of elsinochromes (ESCs) produced by Elsinoë fawcettii..............................................................................................................................47
2-2 Absorption spectrum of the acetone crude extracts of ESCs.............................................48
2-3 Chemical properties of phenolic quinines of the acetone extracted ESCs.........................49
2-4 Reduction of live cells of citrus protoplasts, tobacco protoplasts, or suspension-cultured tobacco cells treated with elsinochrome (ESC) phytotoxins ...............................50
2-5 Cell viability of citrus protoplasts after treatment with elsinochromes (ESCs) isolated from Elsinoë fawcettii with and without antioxidant compounds .....................................51
2-6 Cell viability in suspension-cultured tobacco cells by elsinochromes (ESCs) with antioxidants ........................................................................................................................52
2-7 Development of necrotic lesions on detached rough lemon leaves after a 10-day application of elsinochromes (ESCs) from Elsinoë fawcettii, and prevention of necrosis by co-application of antioxidants.........................................................................53
2-8 Development of necrotic lesions on detached rough lemon leaves 10 days after application of elsinochromes (ESCs) from Elsinoë fawcettii and prevention of necrosis by co-application of superoxide dismutase (SOD) or hyperoxidase ...................54
2-9 Superoxide production assays based on the reduction of nitrotetrazolium blue chloride (NBT) as substrate ...............................................................................................55
2-10 Oxidation of cholesterol by photosensitizers: hematoporphyrin (HP), cercosporin (CR), and elsinochromes (ESCs) under light.....................................................................56
2-11 Leakage of electrolytes from illuminated rough lemon leaf discs treated with elsinochromes (ESCs)........................................................................................................57
3-1 Effects of light and medium compositions on fungal growth and elsinochrome (ESC) production by E. fawcettii ..................................................................................................67
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3-2 ESC accumulation and growth of E. fawcettii at different pH on MM .............................68
3-3 Effects of various carbon sources on fungal growth and ESC production by E. fawcettii assayed on CM medium......................................................................................69
3-4 Effects of nitrogen sources on fungal growth and ESC production by E. fawcettii assayed in MM medium.....................................................................................................70
3-5 Effects of antioxidatants on ESC production by E. fawcettii in MM medium ..................71
3-6 Inhibition of ESC production by Ca2+, Co2+, and Li2+ in E. fawcettii ...............................72
3-7 Effects of the number of fungal colonies and the distances on ESC production by E. fawcettii..............................................................................................................................73
4-1 Putative polyketide synthase, EfPKS1, in Elsinoë fawcettii..............................................91
4-2 Promoter analysis of 1.1 kb sequences upstream of the putative ATG translational start codon of EfPKS1 ........................................................................................................93
4-3 Differential expression of the EfPKS1 gene encoding a fungal polyketide synthase and accumulation of ESC phytotoxins in a wild-type isolate Elsinoë fawcettii ................94
4-4 Strategy of EfPKS1 targeted disruption in Elsinoë fawcettii .............................................95
4-5 EfPKS1 gene expression and ESC production in EfPKS1 disruptants ..............................96
4-6 Pathogenicity assays on detached rough lemon leaves inoculated with agar plugs of wild type, four EfPKS1 disruptants, and two strains expressing a functional EfPKS1 gene of Elsinoë fawcettii ....................................................................................................97
4-7 Pathogenicity assays using conidial suspensions of wild type, the EfPKS1 disruptant, and the complementation strain of Elsinoë fawcettii on detached rough lemon leaves.....98
5-1 Elsinochrome (ESC) biosynthetic gene cluster................................................................120
5-2 Northern-blot analysis of gene expression and elsinochrome (ESC) production in response to nitrogen, pH, and glucose in Elsinoë fawcettii .............................................121
5-3 Targeted gene disruption of TSF1 encoding a putative transcription regulator which contains dual Cys2His2 type zinc finger and GAL4-like Zn2Cys6 binuclear cluster DNA-binding domain using a split-marker strategy in Elsinoë fawcettii........................122
5-4 TSF1 gene expression and ESC production in TSF1 disruptants ....................................123
5-5 Northern-blot hybridization indicates that the ∆tsf1-disrupted mutants failed to accumulate the EfPKS1 and reduce production of RDT1, PRF1 and EfHP1 transcripts.........................................................................................................................124
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5-6 Northern-blot hybridization indicates a feedback inhibition of the ESC clustering genes in Elsinoë fawcettii.................................................................................................125
5-7 Hypothetical reaction pathway for the formation of elsinochromes (ESCs) by function of the ESCs biosynthetic clustering genes.........................................................126
5-8 Hypothetical signal transduction and regulatory controls for ESC biosynthesis and accumulation ....................................................................................................................127
6-1 Thin-layer chromatography analysis (TLC) of ESC phytotoxins (the red/orange pigments) extracted from affected rough lemon leaves inoculated with different isolates of Elsinoë fawcettii .............................................................................................146
6-2 Determination of extracellular enzyme activities in different isolates of Elsinoë fawcettii............................................................................................................................147
6-3 Alleviation of symptom development by co-inoculation of two Elsinoë fawcettii isolates..............................................................................................................................148
6-4 Electrophoresis of the amplified internal transcribed spacer (ITS) rDNA fragments after cleaved with restriction enzymes on 2% agarose gels.............................................149
6-5 Electrophoresis of the amplified partial β-tubulin genes digested with restriction enzymes on 2% agarose gels............................................................................................150
6-6 Electrophoresis of the randomly amplified polymorphic DNA fragments (RAPD) on 2% agarose gels................................................................................................................151
6-7 Comparison of the internal transcribed spacer 1 (ITS 1) sequences between Elsinoë fawcettii Florida isolates and other Elsinoë spp. and other species belonging to the order of Loculoascomycetes via phylogenetic analysis...................................................152
A-1 Spectrophotometric absorbance of elsinochromes (ESCs) treated with 3-(N-morpholino) propanesulfonic acid (MOPS) buffer, nitrotetrazolium blue chloride, or both MOPS and NBT at 560 nm......................................................................................153
C-1 Strategies to obtain full-length of EfPKS1.......................................................................156
D-1 Elsinoë fawcettii hyphae observed using a light microscope...........................................158
D-2 Variation of fungal colony under a dissection microscope..............................................159
D-3 Alignment of nucleotide sequences of fungal partial β-tubulin genes.............................160
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Abstract of Dissertation Presented to the Graduate School of the University of Florida in Partial Fulfillment of the Requirements for the Degree of Doctor of Philosophy
MOLECULAR AND GENETIC DETERMINATION OF THE ROLE OF ELSINOCHROME
TOXINS PRODUCED BY Elsinoë fawcettii CAUSING CITRUS SCAB
By
Hui-Ling Liao
May 2008
Chair: Kuang-Ren Chung Major: Plant Pathology
Citrus scab disease, caused by the fungus Elsinoë fawcettii (Bitancourt & Jenkins), affects
all varieties of citrus, resulting in serious fruit blemishes and economic losses in Florida. My
study focused on genetic determination of the role of elsinochrome phytotoxins produced by E.
fawcettii.
Results indicated that elsinochromes function as photosensitizing compounds that exert
toxicity to plant cells due to production of reactive oxygen species such as singlet oxygen and
superoxides. Upon irradiation to light, elsinochromes alone rapidly killed suspension-cultured
citrus and tobacco cells, induced necrotic lesions on rough lemon leaves, and provoked a steady
increase of electrolyte leakage. The toxicity was drastically decreased or alleviated by the singlet
oxygen quenchers, such as bixin, DABCO, or reduced glutathione. Accumulation of singlet
oxygen and superoxides induced by elsinochromes after irradiation was also detected.
An EfPKS1 gene encoding a fungal polyketide synthase (PKS) was cloned and
characterized from E. fawcettii to confirm the roles of elsinochromes in fungal pathogenesis and
lesion formation by genetic disruption and complementation strategies. In addition, accumulation
of the EfPKS1 transcript and elsinochromes by the wild-type strain were coordinately regulated
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by light, carbon, nitrogen and pH. The results clearly indicate that elsinochromes play a
consequential role in fungal pathogenesis.
The genes involved in the biosynthesis of fungal secondary metabolites are often clustered.
I sequenced a 30-kb region beyond EfPKS1 and identified nine putative genes; some of them
encoding polypeptides are likely required for elsinochrome biosynthesis and regulation. In
addition to EfPKS1, five genes, RDT1 encoding a reductase, OXR1 encoding an oxidoreductase,
TSF1encoding a transcriptional factor, ECT1encoding a membrane transporter, and PRF1
encoding a prefoldin protein subunit were identified. Other four genes (designated as EfHP1-4)
encode hypothetical proteins that are likely not associated with biosynthetic functions. The
involvement of these genes in elsinochrome production was evident by analyzing the TSF1 gene
encoding a putative pathway-specific regulator. Targeted disruption specifically occurred at the
TSF1 gene created fungal mutants that are defective in elsinochrome production. Expression of
the adjacent genes in the TSF1-disrupted mutants was markedly down-regulated.
In addition, elsinochromes were extracted, for the first time, from affected lesions. A
survey of 52 field-collected E. fawcettii isolates in Florida revealed that most of them were able
to produce elsinochromes in cultures and/or in planta. A single isolate (Ef41) with distinct
genetic traits from all others failed to infect rough lemon, grapefruit, and sour orange and
produced no elsinochromes. Overall, my studies employing biochemical, molecular, and
pathological approaches clearly demonstrated that elsinochromes play critical roles for fungal
pathogenesis and lesion development.
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CHAPTER 1 INTRODUCTION AND LITERATURE REVIEW
Biology of Elsinoë fawcettii Causing Citrus Scab
Citrus scab (formerly called sour orange scab) is caused by the pathogenic fungus, Elsinoë
fawcettii Bitancourt & Jenkins (Anamorph: Sphaceloma fawcettii Jenkins) that belongs to the
kingdom Fungi, phylum Ascomycota, class Loculoascomycetes, order Myriangiales, and family
Elsinoaceae (Alexopoulos et al. 1996).
The teleomorph of Elsinoë fawcettii is very rare and has been reported only in Brazil
(Bitancourt and Jenkins 1936a; 1936b). E. fawcettii forms stromata that contain numerous
spherical asci within the pseudothecial locules. Each ascus harbors eight filamentous ascospores
(sexual spores) that are hyaline and oblong elliptical with the size of 5-6 x 10-12 µm (Holliday
1980). Elsinoë spp. produces two kinds of conidia (asexual spores): hyaline conidia and spindle
conidia (Fig. 1-2). Hyaline conidia of Elsinoë spp. are one celled, elliptical, and 2-4 x 4-8 µm
and are the primary source for inoculation (Whiteside et al. 1988). Conidia are produced within
the acervulus which is typically a flat or saucer-shaped bed of conidiophores growing side by
side and arising from a stromatic mass of hyphae (Alexopoulos et al. 1996) and capable of
reproducing by formation of a new germ tube (Holliday 1980; Whiteside et al. 1988). In contrast,
the colored, spindle-shaped conidia that are produced mainly on scab lesions can germinate to
produce hyaline conidia. In culture, E. fawcettii produces raised, slow-glowing colonies that are
usually beige to tan or vinaceous to black. Isolates of E. fawcettii grow slowly in axenic culture,
forming < 10-mm colony size in 30 days. Most strains of E. fawcettii secrete red pigments after
10-15 day incubation in the light.
Identification of citrus scab pathogens is primarily based on their host ranges, because it is
difficult to differentiate based on their morphologies. Elsinoë fawcettii causing common scab
16
was found in many citrus producing areas worldwide. Whiteside (1978; 1984) described two
pathotypes from Florida and later were designated as the “Florida broad host range (FBHR)” and
the “Florida narrow host range (FNHR)” (Timmer et al. 1996). The FBHR pathotype mainly
attacks the leaves and fruits of lemon (C. limon (L.) Burm. F.), sour orange (C. aurantium L.),
grapefruit (C. paradisi Macf.), and Temple/Murcott tangors (C. sinensis (L.) Osbeck x C.
reticulata Blanco), and the fruit of sweet orange (C. sinensis). The FNHR pathotype fail to infect
sour orange, Temple tangor, and sweet orange fruit (Tan et al. 1996; Timmer et al. 1996). All
pathotypes of citrus scab attack rough lemon (Citrus jambhiri Lush).
E. australis Bitancourt & Jenkins (anamorph S. australis Bitancourt & Jenkins.), causing
sweet orange scab differs from E. fawcettii in host ranges and is limited to southern South
America. E. fawcettii rarely causes lesions on sweet orange, whereas E. australis attacks all
sweet oranges as well as some tangerines and their hybrids (Chung and Timmer 2005). Unlike E.
fawcettii that induces lesions on all parts of citrus, E. australis appears to affect only fruit. In
addition, E. australis can be distinguished from E. fawcettii based on the sizes of ascospores (12-
20 x 15-30 µm in E. australis) (Whiteside et al. 1988). Furthermore, E. australis does not
produce spindle-shaped conidia in scab lesions that are often associated with E. fawcettii.
Molecular studies have been employed recently for identification and differentiation of
different species and isolates of Elsinoë (Tan et al. 1996; Timmer et al. 1996; Hyun et al. 2001).
For example: E. fawcettii and E. australis are differentiated by endonuclease restriction analysis
of the amplified internal transcribed spacers (ITSs) of ribosomal DNA. E. fawcettii isolated from
Florida and Australia could be separated by random amplified DNA polymorphism (RAPD)
analysis (Tan et al. 1996).
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In addition to citrus, Elsinoë spp. also cause diseases in a wide range of plants, such as
bean scab caused by E. phaseoli, leaf spot of Dracophyllum sp. caused by E. dracophylli, grape
anthracnose caused by E. ampelina, raspberry anthracnose caused by E. veneta, and twig disease
of Pittosporum tenuifolium caused by E. takoropuku (Phillips 1994; Johnston and Beever 1994;
Agrios 1997; Ridley 2005).
Symptoms, Disease Cycles and Disease Control of Citrus Scab Caused by Elsinoë fawcettii
Symptoms
Citrus scab affects fruit, leaves and twigs of susceptible varieties of citrus (Timmer et al.
2000) (Fig. 1-1). Symptoms start as small, pale orange or buff-colored slightly-raised pustules,
which consist of a mixture of fungal and host tissues. As the pustules develop on most of the
susceptible species and cultivars (e.g., lemons, Satsuma mandarins, Temples, and sour orange),
those spots become warty and creaky protuberance (Fig. 1-1A, and 1-1B). In contrast, on
grapefruit and sweet orange, the lesions appear to be flattened scabby sheets (Fig. 1-1C). The age
of the tissues at the time of infection also affects the elevation and size of lesions. Those formed
on young tissues tend to be raised and those on more mature tissues are flatter. Because of
variations among cultivars and infected-tissue age, it is difficult to differentiate citrus scab from
other citrus diseases on the basis of symptoms alone.
Disease Cycle
In the field, E. fawcettii survives under unfavorable conditions in pustules on leaves, stem
lesions and fruit. Ascospores most likely play no role in the infection process. E. fawcettii
survives in old lesions and produces conidia from acervuli on the surface of scab pustules (Fig.
1-2A). The mode of spread of conidia occurs mostly due to rain splash. Hyaline conidia die
rapidly when exposed to light or dry conditions. After periods of dew, production of spindle-
shaped conidia (Fig. 1-2B) on lesions are stimulated and are spread by wind. A short period of
18
moisture is needed for infection of E. fawcettii after dispersal of conidia. The minimum humidity
period for production of conidia is 1-2 hr, and infection occurs within 2 to 3 hr at 24-27 °C
(Timmer et al. 2000). The severity of citrus scab is markedly affected by wetness. Longer
periods of humidity (up to 24 hr) greatly facilitate infection even at suboptimal temperatures.
Under suitable conditions, scab lesions usually appear on the host, as early as 6 days to 7 days
after infection (Fig. 1-2C and D). Leaves are susceptible immediately after they emerge from the
bud, and become resistant when they are older (about 20 days after emergence). The young fruit
are susceptible until 6-8 weeks after petal fall. The infection often causes fruit to be misshapen
and fall prematurely (Bushong and Timmer 2000).
Disease Control
Citrus scab is a common disease in humid citrus-growing areas in many countries.
Although the damage produced by scab is superficial and does not affect internal fruit quality,
citrus scab reduces acceptability for the fresh-fruit market. Citrus scab is endemic in Florida
where climatic conditions are highly favorable for the pathogen cycle and disease. Scab disease
predominantly affects summer growth flushes as summer rain showers frequently occur in
Florida and produce sufficient wetness for conidial germination and infection. The most effective
strategy recommended for scab management is to remove and destroy the inoculum sources.
Frequent applications of fungicides are absolutely needed to manage citrus scab if the fruit is
intended for the fresh market. Several fungicides such as Topsin® (thiophanate methyl),
Abound® (azoxystrobin), Gem® (trifloxystrobin), Headline®, (pyraclostrobin), ferbam, and
copper fungicides are registered in Florida and can be used for control of citrus scab (Bushong
and Timmer 2000). However, fungicides are often not adequate for disease control. Application
of fungicides also raises concerns on resistance of the pathogens and environmental hazards
(Timmer and Zitko 1997).
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Secondary Metabolites of Fungi
Secondary Metabolites of Fungi
Fungal products classified as secondary metabolites (Turner 1971; Turner and Aldridge
1983) often show significant biological activities or enigmatic properties, and they are not
essential for the microorganisms to complete their lifecycles. Many of those bioactive
compounds (e.g., phytotoxins and melanin) are required for development of diseases or fungal
structures. Some of them may increase fungal fitness, display antimicrobial activity, and
pharmaceutical activities (e.g., antibiotics and immunosuppressant) (Demain and Fang 2000).
Thereby, fungal secondary metabolites have been thought to confer competitive advantages for
the producing microorganisms in natural environments. In addition, fungal secondary
metabolites are of medical, industrial and/or agricultural importance.
Several fungal secondary metabolites have been shown to be associated with fungal
development. For example, linoleic acid-derived compounds produced by A. nidulans (Calvo et
al. 2001), zearalenone from Fusarium graminearum (Wolf and Mirocha 1973), and
butyrolactone I from Aspergillus terreus (Schimmel et al. 1998) are able to enhance sporulation.
Furthermore, dark brown-melanin pigments produced by many fungi by oxidative
polymerization of phenolic compounds function as fungal virulence factors due to their ability to
stimulate production of conidia (e.g., Alternaria alternata), appressoria (e.g., Colletotrichum
lagenarium), sclerotia (e.g., Scherotium spp.), and sexual bodies (e.g., Sordaria macrospora)
(Chet and Hüttermann 1982; Kawamura et al. 1999; Takano et al. 2000; Butler et al. 2001; Engh
et al. 2007). Alternaria alternata produces melanin to enhance the integrity of sexual and asexual
spores (Kawamura et al. 1999). Melanin apparently contributes to the survival of the fungal
spores by protecting against UV light damage. Cercosporin phytotoxin produced by many
20
pathogenic Cercospora spp. is not required for spore development but plays a critical role during
fungal pathogenesis (Choquer et al. 2005; 2007).
Phytotoxins produced by many phytopathogenic fungi often damage plant cells or
influence the course of disease development and the formation of symptoms. Cercosporin
produced by Cercospora spp. and botrydial produced by Botrytis cinerea have been shown to
function as virulence factors and further exacerbate disease severity (Choquer et al. 2005; van
Kan 2006). Phytotoxins are classified into two classes: host-specific and non-host specific. Non-
host specific toxins exhibit general phytotoxicity toward a wide range of plant species including
non-host plants. However, host-specific toxins affect only plant varieties or genotypes that are
the hosts of the producing microorganisms.
Elsinochromes Produced by Elsinoë fawcettii
Many Elsinoë fungal species produce light-activated, red/orange pigments, called
elsinochromes. Elsinochrome pigments containing a phenolic quinine chromophore consist of at
least four derivatives (A, B, C, and D) (Fig. 1-3). The bright red pigments, elsinochromes A, B,
and C were originally isolated from cultures of a pecan pathogen, Elsinoë randii (anamorph:
Sphaceloma randii) and their chemical structures and physical properties have been well
documented (Weiss et al. 1965; Lousberg et al. 1969). Elsinochromes B and C can be quickly
oxidized to A by chromium trioxide (Lousberg et al. 1969). In contrast, elsinochrome D, likely
derived from elsinochrome C by forming a methylenedioxy ring (Fig. 1-3), is an orange pigment
produced only by some Elsinoë species (Shirasugi and Misaki 1992). Elsinochromes are
structural analogs to several polycyclic perylenequinones such as altertoxin I produced by
Alternaria alternata, cercosporin produced by many Cercospora spp., hypericin produced by
Hypericum spp., hypocrellin A produced by Hypocrella bambusae, and phleichrome produced
by Cladosporium spp. (Yoshihara et al. 1975; Assante et al. 1977; Daub 1982a; Duran and Song
21
1986; Stierle and Cardellina 1989; Daub et al. 2005). All of these compounds have a common
4,9-dihydroxyperylene-3,10-quinone chromophore and only differ in attached side chains (Daub
et al. 2005). Additionally, these compounds are grouped as photosensitizers based on their ability
to sensitize cells to visible light, react with oxygen molecules, and produce reactive oxygen
species (ROS) (Yamazaki et al. 1975; Daub 1982a). Light and oxygen are two key components
for photodynamic function and toxicity of these compounds. Although elsinochromes
structurally resemble many photosensitizing perylenequinones, their toxicity has never been
investigated.
Photosensitizing compounds are a group of structurally diverse compounds and natural
products that are able to absorb light energy and are converted to an electronically excited triplet
state. The activated photosensitizers then react with oxygen molecules in two different ways to
form both radical and non-radical species of activated oxygen, including superoxide, hydrogen
peroxide, hydroxyl radical, and singlet oxygen (Dobrowolski and Foote 1983; Girotti 1990) (Fig.
1-4). Activated oxygen species have general toxicity, as they react with biomolecules common to
all cells, including lipids, proteins, and nucleic acids, and often result in cell death (reviewed by
Daub et al. 2005). The toxicities of radical oxygen species have been well known. Several lines
of evidence suggest that the non-radical-singlet oxygen (1O2) is also highly toxic to cells
(reviewed by Daub et al. 2005).
Polyketide Biosynthesis
Polyketides are a large family of natural products that are produced by bacteria, fungi, and
plants. Polyketide chain assembly is catalyzed by polyketide synthase (PKS). Three basic types
of bacterial PKSs are known to date (Shen 2003). Bacterial type I PKSs are modules which
contain one or more large multifunctional protein subunits similar to typical domains of fatty
acid synthases [KS (ketoacyl synthase), AT (acyltransferase), KR (ketoreductase), DH
22
(dehydratase), ER (enoyl reductase), ACP (acyl carrier protein), and TE (thioesterase)]. Each
module harbors a set of distinct, non-iterative activities responsible for the catalysis of one cycle
of polyketide chain elongation. The bacterial type I polyketides which resemble branched-chain
fatty acids include large carboxylic compounds (e.g., deoxyerythronolide B; erythromycin A)
(Cortes et al. 1990; Donadlo et al. 1991; Hutchinson 1999; Staunton and Weissman 2001; Shen
2003). Bacterial type II PKSs are multienzyme complexes that carry a single set of iterative
activities. The type II bacteria polyketides usually contain two or more aromatic rings fused into
polycyclic structures, such as tetracenomycin C, actinorhodin, and doxorubicin (Malpartida and
Hopwood 1984; Motamedi and Hutchinson 1987; Staunton and Weissman 2001; Shen 2003).
Bacterial type III PKSs are iterative homodimeric enzymes that act iteratively and independently
of ACP to synthesize aromatic polyketides, which are often monocyclic or bicyclic, such as
chalcone and stilbene (Funa et al. 1999; Shen 2003).
Fungal secondary metabolites are often synthesized by defined biosynthetic pathways
using various precursors such as shikimic acid, tricarboxylic acid, fatty acid, polyketides,
terpenoids, or amino acids (Keller et al. 2005). Fungal polyketides contain a diverse range of
structures, including a wide range of pigments, mycotoxins, and phytotoxins such as
naphthopyrone, aflatoxin (AF)/sterigmatocystin (ST), fumonisin, lovastatin, compactins,
melanins, and cercosporin.
Carbon skeletons of fungal polyketides are typically synthesized by the fungal iterative
type I PKSs that are composed of a single multifunctional polypeptide with a set of active site
domains similar to a module of bacterial type I PKSs, but they carry out biosynthetic reactions
repeatedly (Shen 2003). Recently, the type III PKSs have been found in some filamentous fungi,
such as Neurospora crassa and Aspergillus oryzae (Seshime et al. 2005; Funa et al. 2007).
23
PKSs are structurally and functionally similar to eukaryotic fatty-acid synthases (FASs),
both catalyzing sequential condensations between ACP (acyl carrier protein)-linked acyl-
thioesters, such as acetyl-CoA and malonyl-CoA (Fig. 1-5) via decarboxylation. However,
fungal type I PKSs do not always process β-keto reduction, dehydration, and enoyl reduction that
are essential for the full processing of the β-carbon in fatty acids. All fungal PKSs contain β-
ketoacyl synthase (KS), acyltransferase (AT) and acyl carrier proteins (ACP) domains for
assembling polyketide backbone, whereas many of them, unlike FASs, lack ketoreductase (KR),
dehydratase (DH) and enoyl reductase (ER) domains (Fig. 1-5A).
Similar to FASs, fungal PKSs iteratively add a two-carbon unit to polyketide chains.
Generally, but not all, biosynthesis of fungal polyketides, such as cercosporin, is initiated when
acetyl and malonyl coenzyme A (CoA) are covalently linked, as thioesters, to the 4’-
phosphopantotheine of an acyl carrier (ACP) domain through the acyltransferase (AT) domain.
Condensation via decarboxylation then occurs with another thioester intermediate that is attached
to the ketoacyl CoA synthase (KS) domain. The KS domain is involved in both chain initiation
and elongation. After condensation, some of β-ketothioesters can be further modified by the
action of other domains such as ketoreductase (KR), dehydratase (DH), or enoyl reductase (ER)
domains if they are present. Further modifications may include cyclization, oxidation, hydration,
and methylation. PKSs that are required for squalestatin biosynthesis in Phoma sp. and fusarin C
production in Fusarium moniliforme and F. venenatum, contain a methyltransferase (MT)
domain that adds methyl groups to the α-carbon of the thioester (Fig. 1-5B) (Hopwood and
Sherman 1990; Bender et al. 1999; Cox et al. 2004; Song et al. 2004).
Once the polyketide chains are completed, they will be released from the enzyme complex
by the function of thioesterase (TE)/cyclase (CYC) domain that also catalyzes further ring
24
closure. Further modification processes involving monoxygenases, dehydrogenases, esterases, O-
methltransferase, reductase, and oxidase contribute to a remarkable diversity of polyketide-
secondary metabolites in nature.
Gene Clusters
Biosynthetic genes that are involved in the production of fungal secondary metabolites are
frequently coordinately regulated and tightly clustered in the genomes (Zhang et al. 2004). Such
examples include the genes involved in the biosynthesis of penicillin by Penicillium spp. (Smith
et al. 1990), cercosporin by Cercospora nicotianae (Chen et al. 2007), aflatoxin
(AF)/sterigmatocystin (ST) by Aspergillus spp. (Yu et al. 2004), ergot alkaloids by Claviceps
pupurea (Tudzynski et al. 1999), fumonisin by Gibberella moniliformis (Proctor et al. 2003),
ochratoxin A by Penicillium nordicum (Karolewiez and Geisen 2005), aurofusarin by Fusarium
graminearum (Malz et al. 2005), and melanin by Alternaria alternate (Kimura and Tsuge 1993).
Regulation of the clustered genes is often governed by a pathway-specific regulator and also
influenced by many global regulatory factors which usually respond to various environmental
cues, such as carbon/nitrogen sources, light, and pH. The gene encoding a pathway-specific
transcription factor is often embedded within the clusters. It is currently unclear why fungal
genes that are responsible for secondary metabolite biosynthesis tend to be clustered. The
clustering of genes in fungi may evolve vertically through meiotic or mitotic processes due to
environmental selections or simply are obtained via horizontal gene transfer from prokaryotes
(Rosewich and Kistler 2000; reviewed by Walton 2000). Horizontal transfer has been proposed
to be a stable transfer of genetic material between microorganisms (Rosewich and Kistler 2000).
Horizontal transfer via assorted processes, such as conjugation, transformation, or transduction in
bacteria is very common. However, the mechanisms involved in horizontal gene transfer in
25
eukaryotes are largely unknown, and no direct evidence is available to explain how horizontal
transfer occurs in eukaryotes including fungi.
Research Overview
The major goal of this research is to determine the function of elsinochromes produced by
Elsinoë fawcettii. Elsinochromes are structurally similar to many photosensitizing
perylenequinones, which has led to speculation that elsinochromes may function as
photosenitizers and are required for fungal virulence during plant-pathogen interactions. In this
study, biochemical, molecular, and genetic approaches were employed to investigate the
virulence determents that are required for Elsinoë fawcettii to invade citrus. Particular
emphasizes was placed on the elsinochromes produced by E. fawcettii. Protocols for extraction
and quantification of elsinochromes were established and the toxicity of elsinochromes to plant
cells was determined to occur through generation of reactive oxygen species, primarily singlet
oxygen and superoxide (Chapter 2). Environmental stimuli affecting production of
elsinochromes in culture was also investigated (Chapter 3). Molecular and genetic approaches
were employed to conclusively determine the role of elsinochromes in fungal pathogenesis and
lesion development by cloning and disruption of an EfPKS1 gene, encoding a fungal type I
polyketide synthase in E. fawcettii (Chapter 4). Chromosome walking and sequence analysis
beyond the EfPKS1 gene allowed identification of additional genes whose products might also be
required for elsinochrome biosynthesis and regulation, indicating that some of the genes
involved in elsinochrome biosynthesis are clustered in the genome of E. fawcettii (Chapter 5).
Targeted disruption of a TSF1 gene encoding a putative transcription regulator generated fungal
mutants that failed to accumulate any measurable elsinochromes and displayed reduced
expression of the genes including EfPKS1 in the cluster (Chapter 5). A survey of 52 isolates of E.
fawcettii obtained from citrus-growing areas in Florida revealed variations in fungal
26
pathogenicity to rough lemon, grapefruit, and sour orange and elsinochrome production among
isolates. DNA polymorphism analyses identified several E. fawcettii variants or pathotypes that
were not previously recognized in Florida (Chapter 6).
27
Figure 1-1. Symptoms of citrus scab caused by the pathogenic fungus, Elsinoë fawcettii. Warty and scabby blister-shaped growths are produced on fruit of Murcutt (A) and Temple (B). C) The infected grapefruit shows the flatter symptoms. D) The infected tangerine leaf is covered with scabby and corky pustules. (Courtesy L. W. Timmer)
28
Figure 1-2. Life cycle of Elsinoë fawcettii, the causal agent of citrus scab (Whiteside 1988; Timmer et al. 2000).
29
Figure 1-3. Structure of elsinochromes with various side-groups (R) (redrawn based on the work of Weiss et al. 1987).
30
Figure 1-4. Proposed model for the formation of activated oxygen species by photosensitizers. The ground-state photosensitizers (0S) absorb light energy, and are converted to the excited singlet (1S) and then long-lived triplet (3S) state. The activated sensitizers may react with oxygen molecules via electron transfers in the presence of a reducing substrate (R) to yield the radical forms of oxygen species, such as superoxide (O2
•-), hydrogen peroxide (H2O2), or the hydroxyl radical (OH•) (type I reaction). Alternatively, triplet sensitizers may react directly with oxygen by an energy transfer reaction to produce non-radical singlet oxygen (1O2) (type II reaction) (Daub and Ehrenshaft 2000).
31
Figure 1-5. Biosynthesis of fatty acid and polyketide in fungi. A) Conserved domains found in
the fungal polyketide synthase (PKS). Fungal type I PKSs produce a single, large polypeptide with multifunctional domains. Formation of the polyketide backbone requires ketoacyl CoA synthase (KS), acyltransferase (AT), and acyl carrier (ACP) domains. Other domains (such as dehydratase (DH), methyltransferase (MT), enoyl reductase (ER), ketoreductase (KR)) in brackets are not essential for all fungal PKSs. B) An overall scheme for fatty acid synthesis and polyketide biosynthesis. In fatty acid synthesis, acetyl-CoA and malonyl-CoA are converted into acetyl-ACP and malonyl-ACP, respectively, by acetyl and malonyl transacylase. Fatty acid synthase (FAS) subsequently condenses the two precursors, via a cycle of reduction, and dehydration in the keto group. Biosynthesis of polyketide in fungi is somewhat similar to fatty acid. Polyketide synthase (PKS), resembling FAS, is responsible for condensation of precursors. The major difference between FAS and PKS is that in addition to acetyl-CoA and malonyl-CoA, PKS may use different substrates as the starter and extender groups. Furthermore, PKSs produce diverse products based on the extent of reduction. The pathways, indicated by the letters (k, n, e, and a), represent various possibilities to yield keto, hydroxyl, enoyl or alkyl group into the growing polyketide chain after each condensation step. The carbon atoms of malonate and acetate contributing to polyketide chain are indicated by numerals. The carbon of malonate that is eliminated as CO2 is indicated by asterisks. The abbreviations: KS, ketoacyl CoA synthase; AT, acyltransferase; DH, dehydrase; MT, methyltransferase; ER, enoyl reductase; KR, ketoreductase; ACP, acyl carrier protein; CYC, cyclase; TE, thioesterase; PT, palmityl transferase. (This figure is redrawn from the work of Hopwood and Sherman 1990; Bender et al. 1999).
32
CHAPTER 2 CELLULAR TOXICITY OF ELSINOCHROME PHYTOTOXINS PRODUCED BY Elsinoë
fawcettii
Elsinochrome pigments (ESCs) were extracted from mycelia of cultured Elsinoë fawcettii
by acetone and tested for cellular toxicity in this chapter. Thin-layer chromatography (TLC)
analysis was used to separate and identify at least five different derivatives of ESCs. A spectrum
scanning analysis of the crude extract of ESCs as well as the five distinct bands recovered from
TLC plates revealed an identical absorbance spectrum, showing a major absorbance at 460 nm
with two minor peaks at 530 and 570 nm. Chemical analyses revealed that the pigments
extracted from E. fawcettii cultures contain phenolic quinines, resembling ESC phytotoxins that
have been characterized in other Elsinoë spp. Upon irradiation with light, ESCs rapidly killed
suspension-cultured citrus and tobacco cells. The toxicity was decreased by adding the singlet
oxygen (1O2) quenchers, bixin (carotenoid carboxylic acid), DABCO (1, 4-diazabicyco octane),
the ascorbate, or reduced glutathione. Application of ESCs onto rough lemon leaves induced
necrotic lesions, whereas lesion development was inhibited by the addition of bixin, DABCO, or
ascorbate, but not α-tocopherol. Incubation of rough lemon leaf discs with ESCs in the light
resulted in a steady increase of electrolyte leakage. Similar with two photosensitizing compounds,
hematoporphyrin and cercosporin, the accumulation of 1O2 by ESCs after irradiation was
indicated by successful detection of the cholesterol oxidation product, 5α-hydroperoxide.
Addition of a potent quencher, β-carotene, prevented 5α-hydroperoxide production. ESCs
generated superoxide ions (O2 ▪-), whereas accumulation of O2
•- was blocked by addition of the
superoxide dismutase, a scavenger of O2•-, but not the 1O2-quencher, DABCO. These
experiments indicated that ESCs function as photosensitizing compounds that produce 1O2 and
O2•-, and exert toxicity to plant cells.
33
Introduction
Elsinoë fawcettii Bitancourt & Jenkins is the causal agent of citrus scab. This disease is
widely distributed, occurring in many citrus growing areas where rainfall conditions are
conducive for infection. Conidia (asexual spores) are produced from the imperfect stage of the
fungus, Sphaceloma fawcettii Jenkins, and serve as the primary source for inoculation in the field
(Hyun et al. 2001).
A large number of Elsinoë species are able to produce red pigments, named elsinochromes
(ESCs) (Meille et al. 1989). The structures of ESCs have been well established (Weiss et al.
1957; Weiss et al. 1965; Meille et al. 1989). ESCs contain at least four derivatives, A, B, C and
D, differing in side groups. Those derivatives all have a basic 4,9-dihydroxyperylene-3,10-
quinone chromophore similar to several perylenequinone compounds grouped as
photosensitizers based on their ability to sensitize cells to visible light and produce reactive
oxygen species (ROS) (Yamazaki et al. 1975; Daub 1982a). Light and oxygen are absolutely
required for the photodynamic function and toxicity of these compounds. Photosensitizing
compounds absorb light energy and convert to a stable electronically excited state (triplet state)
which in turn reacts with oxygen to produce toxic reactive oxygen species (ROS) such as
superoxides (O2•-), hydrogen peroxide (H2O2), hydroxyl radical (OH•), and/or singlet oxygen
(1O2) (Dobrowolski and Foote 1983; Girotti 1990). In the Type I reaction, the activated triplet
photosensitizers can react with oxygen molecules directly by transferring a hydrogen atom or
electron from reducing substrates (such as NADPH, ascorbate, and L-cysteine), resulting in
reduced oxygen species including superoxides (O2•-) (Girotti 1990). In the Type II reaction, the
activated photosensitizers react with oxygen molecules by an energy-transfer process, producing
electronically reactive singlet oxygen (1O2) (Spikes 1989).
34
Both 1O2 and O2•- are toxic to cells, causing the oxidation of various biological components
including fatty acids, membranes, proteins/enzymes, sugars, and nucleic acids, and often
resulting in cell death (reviewed by Daub et al. 2005). Many of the perylenequinone pigments
produced by fungi have been shown: 1) to be toxic to mice, bacteria, and many fungi, 2) to be
cytotoxic to animal tumors, 3) to be potent antiviral agents, and 4) to inactivate protein kinase C
(Tamaoki and Nakano 1990; Hudson and Towers 1991; Diwu 1995; Hudson et al. 1997). Except
for cercosporin produced by many members of the fungal genus Cercospora (Callahan et al.
1999; Choquer et al. 2005; 2007; Chen et al. 2007; Dekkers et al. 2007; Chen et al. 2007), none
of the perylenequinones of fungal origin have been demonstrated to act as a crucial factor in
plant diseases caused by the producing pathogen.
Many E. fawcettii isolates collected from Florida citrus growing areas produce red/orange
pigments in culture (see details in Chapter 6). However, the identity of these pigments remains
unknown. The aim of this study is first to isolate and characterize the pigments from E. fawcettii.
This chapter describes methodology for isolation and analysis of the extracted pigments and
reports their physical and chemical properties as ESC phytotoxins that have been described
elsewhere by Weiss and his colleagues (1987). In addition, the extracted ESC-like pigments from
one of the E. fawcettii isolates are demonstrated to be toxic to host and non-host plant cells.
Evidence is also presented for function of ESCs as photosensitizing agents in culture and in
planta, by producing toxic reactive oxygen species, mainly 1O2 and O2•-.
Materials and Methods
Biological Materials and Cultural Conditions
E. fawcettii Bitancourt & Jenkins (anamorph: Sphaceloma fawcettii Jenkins) CAL WH-1
isolate used in this study was single-conidium isolate from scab affected calamondin (Citrus
madurensis Lour) fruit in Florida and was kindly provided by L. W. Timmer (University of
35
Florida, Citrus Research and Education Center, Lake Alfred, FL). The fungus was grown on a
sterilized filter paper, and stored at -20 °C for long-term storage. Fungal cultures were routinely
maintained on potato dextrose agar (PDA, Difco, Becton, Dickinson and Company, Sparks, MD,
USA). For toxin production, fungal mycelia were minced with a sterile blender, spread on PDA
and incubated under continuous fluorescent light for 5 days as previously described (Liao and
Chung 2008a).
A cell suspension of tobacco (Nicotiana tabacum cv. Xanthi) was kindly provided by D. J.
Lewandowski (Ohio State University, Columbus, OH, USA) and maintained in a Murashige and
Skoog medium (Murashige and Skoog 1962) with gentle agitation under a daily regime of 16-h
light and 8-h dark. Plant cells were subcultured weekly in a freshly prepared medium for toxicity
assays. For protoplast isolation, 4-day-old tobacco cells were harvested and digested with cell-
wall degrading enzymes (a mixture of 1.5 % cellulase and 0.15 % pectolyase) as described by
Lewandowski and Dawson (1998). Sweet orange (Citrus sinensis (L.) Osbeck) suspension cells,
kindly provided by J. W. Grosser (University of Florida, CREC, Lake Alfred, FL, USA), were
maintained in a Murashige and Tucker medium (1969). Citrus protoplasts were prepared by
incubating with 10 % of cell wall degrading enzyme complex (Sigma-Aldrich, St. Louis, MO)
for 2 h as described by Grosser et al. (1988). Rough lemon (Citrus jambhiri Lush) trees were
maintained in greenhouse and rapidly expanding immature leaves approx. 13-20 mm length and
4-7 mm wide, were harvested for toxicity assays.
Isolation and Analysis of the Red/Orange Pigments
The orange/red pigments secreted in culture were extracted twice from dried agar medium
bearing fungal mycelia with acetone for 16 h. Organic solvent was combined and evaporated
with a Model R110 of Rotavapor (Brinkmann, Buchi, Switzerland). For thin-layer
chromatography (TLC) analysis, the pigments were dissolved in acetone, spotted onto TLC
36
plates coated with a 60 F254 fluorescent silica gel (5 x 20 cm, Selecto Scientific, Suwanee, GA,
USA), and separated with a solvent system containing chloroform and ethyl acetate (1:1, v:v).
The crude extracts separated by TLC were examined by a hand-held long wavelength UV lamp
(UVP, San Gabriel, CA, USA). After separation, the pigments showing distinct bands were
scraped from the TLC plate, dissolved in acetone, and separated from silica gel by low-speed
centrifugation. The acetone was dried and the amounts of ESCs recovered were determined by
weight. The pigments dissolved in acetone were examined by spectrophotometry at absorbance
between 400 and 650 nm. Cercosporin was purified from cultures of Cercospora nicotianae in
separate studies (Choquer et al. 2005; Chen et al. 2007). The extracted ESC toxins were directly
mixed with plant cells for toxicity assays. Unless otherwise indicated, all chemicals were
purchased from Sigma-Aldrich (St. Louis, MO, USA).
Toxicity Assays to Plant Cells
Citrus or tobacco suspension cells or protoplasts at density 1 x 106 mL-1 were mixed with
various concentrations of ESCs (dissolved in acetone) with or without singlet oxygen (1O2)
quenchers, and placed on the top of 1 % agarose (in a 35 x 10 mm Petri dish). Cell cultures were
illuminated with fluorescent lights at an intensity of 3.5 J m-2 s-1 at room temperature (~25 °C)
for citrus cells or at 32 °C for tobacco cells. Light intensity was determined by a Dual-Display
light meter (Control Company, Friendswood, TX, USA). Dark-grown cultures were wrapped in
aluminum foil and incubated in the same conditions. Cells were examined over time by staining
with 1 % Evan’s blue (Taylor and West, 1980). Dead cells were stained blue as they cannot
exclude Evan’s blue, whereas live cells remained clear. Cell viability was determined with the
aid of a hemocytometer using a microscope at x100 magnification. The percentage of cell
viability was calculated by the number of live cells divided by the total number of cells
37
examined. Control cultures were untreated or cells treated with equal volumes of acetone and/or
other solvents (final concentration < 1%) as appropriate.
The toxicity of ESCs on host plants was determined on detached rough lemon leaves (4-7
days after emergence). ESCs (1 mM, cercosporin equivalent) with or without antioxidants were
applied onto the surface of rough lemon leaves and incubated in a moist chamber under
fluorescent light (3.5 J m-2 s-1), and monitored daily for development of necrotic lesions.
Antioxidants used in this study include: bixin (carotenoid carboxylic acid), β-carotene, DABCO
(1,4-diazabicyco octane), α-tocopherol (vitamin E), reduced glutathione, L-cysteine, and (+)-
sodium L-ascorbate (vitamin C). Bixin, β-carotene, and α-tocopherol were dissolved in 95 %
ethanol and others were dissolved in water to make a stock solution.
Detection of Singlet Oxygen and Superoxide Ions
Production of 1O2 by ESCs upon irradiation was determined by their ability to oxidize
cholesterol by the protocol of Daub and Hangarter (1983) with modifications. The 1O2-
generating photosensitizers, hematoporphyrin and cercosporin, were used as the positive
controls. Photosensitizing compounds (8 mg each) in 20 mL pyridine were mixed with
cholesterol (200 mg), and irradiated under a fluorescent light at intensity of 2.2 joules m-2 s-1
with gentle bubbling for 5 h. After solvent was removed, the oxidized products were suspended
in 20 mL of hot methanol, passed through a filter to remove precipitation after cooling, and
analyzed by TLC with a solvent system containing hexane-isopropanol (9:1 or 24:1, v:v). The
oxidized products of cholesterol were visualized as bands after staining with a chromogenic
reagent, N, N-dimethyl-p-phenylenediamine (1 %) dissolved in methanol-H2O-glacial acetic acid
(5:5:0.1, v/v/v) (Smith and Hill 1972; Smith et al. 1973). The cholesterol 5α-hydroperoxide
standard was prepared by photo-oxidation with hematoporphyrin as described by Ramm and
Caspi (1969).
38
Photochemical reduction of nitrotetrazolium blue chloride (NTB) was used to determine
O2•- production by ESCs (Daub and Hangarter 1983). Reactions were carried out in a solution
containing 5 mM 3-(N-morpholino) propanesulfonic acid (MOPS), 10 mM methionine (as a
reducing agent), 2.5 mM NBT, 2 µM riboflavin, 10 µM of ESCs or cercosporin, and superoxide
dismutase (SOD, 1 mg mL-1) or DABCO (1 mM). Nitrotetrazolium blue chloride was added into
the buffer before the addition of photosensitizers and the reaction mixture was irradiated under a
constant light at intensity of 4.7 J m-2 s-1. Superoxide production, as shown the increase
absorbance at 560 nm as a result of the reduction of NBT, was measured spectrophotometrically
(Beruchamp and Fridovich 1971).
Determination of Electrolyte Leakage
Electrolyte leakage was measured by the method of Alferez et al. (2006) with some
modifications. Leaf discs (0.5 cm in diameter) were cut from 4-day-old rough lemon leaves,
placed in a 96-well microtiter plate, and incubated with ESCs (2 mM; dissolved in 7 % acetone)
under constant fluorescent light (3.5 J m-2 s-1) or in complete darkness at room temperature.
Control leaf discs were treated with equal amounts of acetone or deionizer water as appropriate.
Leaf discs (10) were randomly collected at 12-h intervals, soaked in water for an additional 1 h
on a rotary shaker (60 r.p.m.), and measured for initial conductivity (IC). Leaf samples were
immediately frozen in liquid nitrogen and kept at -80 °C for at least 12 h to obtain the remain
conductivity of leaves. Total conductivity (TC) of leaves was determined after leaf discs were
thawed at room temperature for 10-15 min. Conductivity was determined by a Model 115 Orion
conductivity meter equipped with a Pentrode probe (Thermo Electron, Boston, MA, USA).
Electrolyte leakage, expressed as percentage of total conductivity, was calculated by dividing
initial conductivity (IC) by total conductivity (TC).
39
Statistical Analysis
Data were analyzed by ANOVA using SAS (PROCGLM) for PC (SAS Institute Inc., Cary,
N.C.). When differences were significant (P < 0.05), individual treatment means were separated
using Ducan’s Multiple Range Test (P = 0.05).
Results
Isolation and Characterization of ESCs from Elsinoë fawcettii
Acetone extracts from cultures of an E. fawcettii isolate produced five distinct bands after
TLC separation (Fig. 2-1). Bands 1, 2, and 3 [in order of decreasing Rf value (the ratio of the
distance migrated by a substance compared with the solvent front)] appeared to be major
compounds of the extracts based on band width, whereas bands 4 and 5 appeared to be minor
compounds. Spectrophotometric scanning revealed that the acetone extracted pigments displayed
a strong absorbance at 460 nm with two minor peaks at 530 and 570 nm (Fig. 2-2A) which
resembles the ESCs previously isolated from several Elsinoë species (Weiss et al. 1957; 1965).
Further analysis indicated that all five bands, recovered from TLC plates had similar absorption
spectra, also displaying three major absorption peaks at 460, 530 and 570 nm (Fig. 2-2B, C, D, E,
and F). In addition, the red/orange pigments from E. fawcettii had several typical characteristics
of ESCs containing phenolic quinines. Similar to ESCs described by Weiss et al. (1957; 1987),
the extracted red/orange pigments became bright green when dissolved in aqueous KOH or
sodium carbonate (Fig. 2-3). Further, the green pigment reverted to pink when alkaline sodium
dithionite was added (Fig. 2-3A). The green pigment changed to a distinct leuco compound,
showing yellow/greenish fluorescence when treated with zinc dust (Fig. 2-3B). These results
indicated that the red/orange pigments extracted from E. fawcettii were ESCs.
40
Toxicity of ESCs from E. fawcettii to Host and Non-Host Cells
The toxicity of ESCs was assayed using citrus protoplasts. As shown in Fig. 2-4A, ESCs
exhibited dosage-response toxicities with respect to citrus protoplasts. At 10 µM, no viable citrus
cells remained after 5 h in the light. At 5 µM, there was a decrease in the rate of cell death
throughout the assay period. By contrast, untreated citrus cells or cells treated with acetone alone
remained viable throughout the assay period. ESCs did not produce a toxic reaction when cells
were incubated in complete darkness.
The toxic effect of ESCs was also evaluated with suspension-cultured tobacco cells and
protoplasts. Similar to cercosporin produced by a tobacco pathogen, C. nicotianae (Daub 1982a),
ESCs caused rapid death of tobacco protoplasts (Fig. 2-4B) or cultured suspension cells (Fig. 2-
4C), in a dose-response manner within 1 h after irradiation with light. Untreated or acetone-
treated tobacco cells in the light or cells incubated in the darkness remained viable for the
duration of the experiment.
Antioxidants Reduce ESC Toxicity
The toxicity of ESCs was alleviated to various degrees by adding 400 µM bixin (Fig. 2-
5A), 2 mM DABCO or 4 mM of ascorbate, or reduced glutathione (Fig. 2-5B-D). Compared
with bixin, DABCO, and ascorbate, reduced glutathione had less effect on the protection against
toxicity of ESCs, by showing an extended lag period. Application of antioxidants with lower
concentrations had little or no effect on reduction of toxicity by ESCs (data not shown). Addition
of α-tocopherol or L-cysteine (4 mM each) appeared to enhance elsinochrome phytotoxicity as
the duration of incubation increased (Fig. 2-5E and F).
Similar to citrus protoplasts, the cellular toxicity of ESCs to suspension-cultured tobacco
cells was alleviated by the addition of antioxidants such as bixin, DABCO, ascorbate, and α-
tocopherol (Fig. 2-6A-D). In the presence of bixin or DABCO, over 40 % of tobacco cells were
41
viable after incubation with ESCs for 24 h in the light. Both ascorbate and α-tocopherol
significantly delayed photo-induced cell death (by at least 18 h), yet neither compound was able
to protect cell death beyond 24 h. Untreated tobacco cells incubated in the dark were healthy for
the duration of the experiment (The inset of Fig. 2-4C).
ESCs are Toxic to Citrus Leaves
To determine if ESCs were toxic to the host, the crude extracts were applied onto detached
rough lemon leaves. After incubated for 10 days, the ESC-treated spots on rough lemon leaves
developed noticeable necrosis in the light (Fig. 2-7). Leaves treated with the solvent alone didn’t
developed necrosis (Fig. 2-7). Mixture of ESCs with bixin, DABCO, or ascorbate on the leaves
prevented development of necrosis on detached rough lemon leaves (Fig. 2-7A-C). Bixin showed
a light brown color when dissolved in 95 % ethanol. Application of α-tocopherol alone, however,
resulted in a brownish necrotic spot and failed to alleviate the toxicity of ESCs (Fig. 2-7D).
Application of superoxide dismutase (SOD) or hyperoxidase also had effects on protection
against the toxicity of ESCs on rough lemon leaves (Fig. 2-8).
Production of Reactive Oxygen Species by ESCs
Production of O2•- by ESCs was evaluated with a superoxide scavenging assay (Beruchamp
and Fridovich 1971; Daub and Hangarter 1983) based on its ability to reduce nitrotetrazolium
blue chloride (NTB), and compared with the levels of O2•- induced by other photosensitizing
compounds such as cercosporin and riboflavin known to generate O2•- (Oster et al. 1962; Daub
and Hangarter 1983). In the absence of NTB, photosensitizers dissolved in the MOPS buffer
produced lower absorbance values at 560 nm (Fig. 2-9A; Fig. A-1), representing the reaction
baseline. Mixing NTB with the crude extracts of ESCs significantly elevated absorbance values
because of reduction of NTB (Fig. 2-9A). However, the reactions were repressed in the presence
of O2•- scavenging enzyme, SOD, indicating the production of superoxide. Compared with
42
cercosporin and riboflavin, ESCs appeared to induce high levels of O2•- after irradiation (Fig. 2-
9B). Addition of SOD, but not DABCO, drastically reduced the accumulation of superoxides
from the actions of ESCs (Fig. 2-9C).
Production of cholesterol 5α-hydroperoxide from cholesterol is one of the best and
simplest ways to test for the presence of 1O2 (Kulig and Smith 1973). To assess the production of
1O2 in vitro, the extracted ESCs were mixed with cholesterol and illuminated. The resulting
products were chromatographed in two different solvent systems and detected as distinct bands
after staining with a chromogenic reagent, N, N-dimethyl-p-phenylenediamine. Reaction of
cholesterol 5α-hydroperoxide with dimethyl-p-phenylenediamine resulted in pink pigments on
the TLC plate which turned dark green 2h after staining. As with hematoporphyrin (positive
control) and cercosporin photosensitizers, ESCs converted cholesterol by 1O2-induced
photodynamic oxidation into the 5α-hydroperoxides of cholesterol in the light (Rf 0.4 and 0.1 in
Fig. 2-10A and B, respectively). No visible band was detected from the untreated cholesterol.
Irradiation of cholesterol with UV light (240 nm) for 24h yielded several bands on TLC, but no
cholesterol 5α-hydroperoxide was detected (Fig. 2-10C). A faint band with slightly faster
migration of unknown identity was detected in products generated by cercosporin and ESCs. The
cholesterol 5α-hydroperoxides and the faint bands were undetectable when β-carotene, a potent
1O2 quencher, was added to the reaction mixture.
Electrolyte Leakage Induced by ESCs
When incubated with illumination for 24 h, the extracted ESCs induced an increase in
electrolyte leakage of rough lemon leaf discs (Fig. 2-11A). Leaf discs treated with water or
solvent alone, or leaf discs incubated in the dark showed relatively minor electrolyte leakage.
Electrolyte leakage induced by ESCs in the light steadily increased over time, whereas leakage
of the controls remained low (Fig. 2-11B).
43
Discussion
Elsinoë fawcettii isolates obtained in Florida citrus-growing areas produced red/orange
pigments in culture similar to ESCs produced by many Elsinoë spp. (Weiss et al. 1957; 1987),
and had a visible absorption spectra characteristic of ESCs. In addition, the orange/red pigments
had other typical characteristics of ESCs, such as forming a distinct yellow/greenish fluorescence
leuco compound when reacted with zinc dust in alkaline conditions (Weiss et al. 1957; 1987),
sparing solubility in water, but readily soluble in several organic solvents, such as acetyl acetate
and acetone. Thin-layer chromatography analysis of the acetone-extracted pigments revealed
significant variations of the pigments produced in culture. The results strongly suggest that these
pigments were ESC analogs containing a phenolic quinine chromophore.
Compared with studies of chemical characterization, little is known about the biological
function of ESCs. The photodynamic action of ESCs leading to cellular toxicity has been
predicted based on their structural similarity to many photosensitizing compounds such as
cercosporin, hypericin, or hypocrellin A (Daub et al. 2005), yet this has never been demonstrated
experimentally. In the present study evidence is presented for ESCs’ toxicity to plant cells by
functioning as photosensitizers that generate reactive oxygen species (ROS). Since citrus
suspension cells aggregated to form massive clumps in culture, the toxicity assays were
performed only with citrus protoplasts. ESCs extracted from E. fawcettii rapidly killed citrus
protoplasts in a dose-dependent manner and only when cells were exposed to the light, consistent
with the mode of action for other photosensitizing compounds (Yamazaki et al. 1975; Daub
1982a; Spikes 1989). The cellular toxicity of ESCs was attenuated considerably when
antioxidant compounds were added into the culture, implying the involvement of reactive
oxygen species, particularly O2•- and/or 1O2. Carotenoids are efficient 1O2 quenchers in the
biological systems (Krinksy 1979). Bixin, a carotenoid carboxylic acid, has a lower molecular
44
weight than β-carotene and is more polar owing mainly to the presence of the carboxylic acid
group (Daub 1982a). Both bixin and β-carotene have the same isoprenoid chain length but bixin
is more soluble in aqueous solutions. Carotenoids quench 1O2 via energy transfer mechanisms
(Foote and Denny 1968; Foote et al. 1970) and are slowly consumed in the reaction.
DABCO (1,4-Diazabicyclo octane) also is an effective 1O2 quencher. Unlike bixin,
DABCO quenches 1O2 by a chemical reaction, and is quickly consumed (Oannes and Wilson
1968; Daub 1982a). These contrasting properties may account for why bixin provided a more
persistent protection of citrus cells than DABCO (Figs 2-5 and 2-6). In addition, the red
pigmented ESCs became bright green when dissolved in aqueous DABCO, indicating a direct
interaction between DABCO and ESCs. Both bixin and DABCO have been shown to decrease
the toxicity of cercosporin to tobacco cells (Daub 1982a). ESCs were also toxic to tobacco, a
nonhost plant of E. fawcettii. Similarly, addition of antioxidants also provided some protection
against the toxicity of ESCs, indicating a nonhost specificity of ESCs. The antioxidants bixin,
DABCO and ascorbic acid but not α-tocopherol decreased the toxicity of ESCs in culture and
provided some protection on detached rough lemon leaves. However, the concentrations required
for protection in planta were far higher than those in culture, likely owing to the poor penetration
of antioxidants through the cuticle. Both ascorbic acid and the reduced form of glutathione were
also effective in protecting citrus cells against ESCs. By contrast, L-cysteine and α-tocopherol
had little or no effect on cellular protection against ESCs in culture and on citrus leaves.
Application of α-tocopherol alone at a concentration of 500 mM on young rough lemon leaves
induced necrosis. However, α-tocopherol provided some levels of protection against the toxicity
of ESCs to tobacco cells. α-tocopherol, with a well-known ability to terminate radical chain
oxidation by binding to cell membranes, has been often used in studies of nutritional or cell
45
membrane functions (Tinberg and Barber 1970; Tappel 1972). The requirement of α-tocopherol
binding to membranes may contribute to its ineffectiveness in cellular protection against ESCs
for citrus protoplasts and leaf tissues.
Photosensitizing compounds are able to generate reactive oxygen species upon activation
by light (Yamazaki et al. 1975; Daub 1982a; Dobrowolski and Foote 1983; Spikes 1989; Girotti
1990). Results derived from this study on the toxic effect of ESCs in vitro and in vivo confirm
that ESCs are damaging to citrus cells by the production of both O2•- and 1O2. This study has
demonstrated that antioxidants such as bixin, DABCO, and others capable of quenching 1O2
provide substantial protection from the toxicity of ESCs in both cultured citrus and tobacco cells
and on rough lemon leaves. Production of 1O2 by ESCs was confirmed by successful detection of
the cholesterol. 5α-hydroperoxide that is solely produced through the oxidation of cholesterol by
1O2 (Kulig and Smith 1973), which is one of the best indications of 1O2 production versus
production of O2•- and other free radicals (Smith et al. 1973). Oxidation of cholesterol by O2
•-,
UV or other radicals often generates multiple products, mainly the 7α- and 7β-hydroperoxides,
but never produce the 5α-hydroperoxide (Smith et al. 1973). By contrast, the oxidizing reaction
of 1O2 with cholesterol primarily produces the 5α-hydroperoxide. Addition of β-carotene, an
effective 1O2 quencher, completely prevented the production of the 5α-hydroperoxide by
hematoporphyrin, cercosporin and ESCs. Therefore, positive detection of the cholesterol 5α-
hydroperoxide indicates that ESCs were able to generate 1O2 after exposure to light. Singlet
oxygen is highly reactive and has been shown to be toxic to a wide range of cells (Foote and
Denny 1968; Foote et al. 1970; Daub and Ehrenshaft 2000). The results strongly implicate the
involvement of 1O2 in the toxicity of ESCs because 1O2 quenchers reduced cultured citrus cell
mortality and prevented necrosis on host leaves.
46
Production of O2•- by ESCs was demonstrated by a superoxide production assay used to
determine SOD enzymatic activity with NTB as substrate (Beruchamp and Fridovich 1971; Daub
and Hangarter 1983). It seemed that ESCs produced O2•- more efficiently than cercosporin.
Reduction of NTB induced by ESCs was inhibited by adding the O2•- scavenging enzyme (SOD)
but not the 1O2 quencher, providing evidence to support that photodynamic reaction of ESCs also
generates O2•-. The detection of O2
•- has important implication for involvement in ESC toxicity
since O2•- also is toxic in biological systems.
To explore the potential toxic mechanisms of ESCs, electrolyte leakage of rough lemon
leaf discs was measured after treatment with ESCs. Treatment with ESCs under light induced
higher electrolyte leakage than water or solvent controls. The results suggested that ESCs
damage cell membranes, likely by inducing lipid peroxidation as demonstrated in cercosporin-
treated tobacco tissues (Daub 1982b). Unlike the rapidly (< 2 min) induced electrolyte leakage
caused by cercosporin in tobacco, ESC-induced ion leakage was not observed until several hours
after irradiation, indicating that the toxic activity on citrus membranes might not be direct.
Alternatively, this slow response of electrolyte leakage might result from the complexity of cell
membranes of citrus or the structure of its cuticle. Disruption of cell membranes followed by
nutrient release is beneficial to the invading pathogen. Therefore, ESCs may play a critical role
in pathogenesis during fungal penetration and colonization.
47
Figure 2-1. Thin-layer chromatography analysis of elsinochromes (ESCs) produced by Elsinoë
fawcettii and compared to cercosporin (CR) extracted from a tobacco pathogen, Cercospora nicotianae. ESCs were extracted from agar plugs containing fungal mycelium with acetone, spotted onto a silica gel plate, and separated with chloroform and ethyl acetate, resulting in five distinct (red/orange) bands with Rf values (1-5).
48
Figure 2-2. Absorption spectrum of the acetone crude extracts of ESCs (A), and individual
bands, 1, 2, 3, 4 and 5, recovered from TLC plate (B, C, D, E, and F), showing three major peaks at 460, 530 and 570 nm. Solvent alone (acetone) and pure cercosporin (CR) (Sigma-Aldrich) were also used as controls (G and H).
49
Figure 2-3. Chemical properties of phenolic quinines of the acetone extracted ESCs. The
red/orange pigments appear bright green in color when dissolved in aqueous KOH or sodium carbonate. A) The green color was changed to a pink color when alkaline sodium dithionite was added. B) The green color was changed to yellow/greenish fluorescence immediately after treated with zinc dust in acidic conditions under UV light (365 nm). In all cases, acetone alone was used as a negative control.
50
Figure 2-4. Reduction of live cells (%) of citrus protoplasts (A), tobacco protoplasts (B), or suspension-cultured tobacco cells (C) treated with elsinochrome (ESC) phytotoxins produced by Elsinoë fawcettii or Cercosporin (CR) toxin extracted from a tobacco pathogen, Cercospora nicotianae, and incubated under constant fluorescent light or in the darkness. Cell viability of citrus protoplasts in the darkness was determined only at 6 h after incubation (A). Insets indicate viability of plant cells incubated in the dark. Data represent the means of two different experiments with at least three replicates. Vertical bars represent standard deviation.
51
Figure 2-5. Cell viability (% live cells) of citrus protoplasts after treatment with elsinochromes (ESCs) isolated from Elsinoë fawcettii with and without antioxidant compounds: A) 400 µM bixin (carotenoid carboxylic acid); B) 2 mM DABCO (1,4-diazabicyco octane); C) 4 mM L-ascorbic acid; D) 4 mM reduced glutathione; E) 4 mM α-tocopherol; and F) 4 mM L-cysteine. Citrus protoplasts (1 x 106) were mixed with or without ESCs (5 µM, cercosporin equivalent) and antioxidants as indicated under constant fluorescent light. The controls were treated with acetone-H2O or acetone-95% ethanol as appropriate. Data represent the means of two different experiments with at least three replicates. Vertical bars represent standard deviation. Open circles, control; closed circles, antioxidant; open triangles, ESCs; closed squares, ESCs + antioxidant.
52
Figure 2-6. Cell viability (% live cells) in suspension-cultured tobacco cells by 1µM elsinochromes (ESCs) with antioxidants (400 µM bixin (carotenoid carboxylic acid), 2 mM DABCO (1,4-diazabicyco octane), 4 mM of L-ascorbic acid, or α-tocopherol). Tobacco cells (1 x 106) were treated with ESCs in the presence or absence of antioxidants, as indicated, and incubated under constant fluorescent light. Data represent the means of two different experiments with at least three replicates. Vertical bars represent standard deviation. Open circles, control (1 µL acetone-ethanol); closed circles, antioxidant; open triangles, ESCs; closed squares, ESCs + antioxidant.
53
Figure 2-7. Development of necrotic lesions on detached rough lemon leaves after a 10-day application of 1 mM elsinochromes (ESCs) from Elsinoë fawcettii, and prevention of necrosis by co-application of antioxidants, A) 100 mM bixin (carotenoid carboxylic acid), B) 300 mM of DABCO (1,4-diazabicyco octane), C) 300 mM L-ascorbic acid, or D) 500 mM α-tocopherol). Citrus leaves were treated with or without ESCs and antioxidants as indicated and incubated in a moist chamber under a constant fluorescent light. The mocks were treated with equal volume (3 µL) of water, 95% ethanol, and/or acetone as appropriate.
54
Figure 2-8. Development of necrotic lesions on detached rough lemon leaves 10 days after application of 100 μM elsinochromes (ESCs) from Elsinoë fawcettii. Co-application of ESCs and 100 μM superoxide dismutase (SOD) or 100 μg μL-1 hyperoxidase prevents lesion formation induced by ESCs alone. Citrus leaves were treated with or without ESCs and superoxide dismutase and hyperoxidase as indicated and incubated in a moist chamber under a constant fluorescent light. The mocks were treated with equal volume (3 µL) of water and/or acetone as appropriate.
55
Figure 2-9. Superoxide production assays based on the reduction of nitrotetrazolium blue chloride (NBT) as substrate. A) Spectrophotometric absorbance of elsinochromes (ESCs) alone (open bars) or ESCs treated with NBT with (hatched bars) or without (closed bars) superoxide dismutase (SOD) in the 3-(N-morpholino) propanesulfonic acid (MOPS) buffer at 560 nm. B) Accumulation of superoxide ions (O2
•-) by photosensitizing compounds riboflavin (circles), cercosporin (squares) extracted from Cercospora nicotianae, and ESCs (triangles) extracted from cultures of Elsinoë fawcettii after irradiation with light. The respective photosensitizers were dissolved in buffer and used as the blanks. C) Suppression of ESC-induced superoxide accumulation by addition of SOD but not DABCO (1,4-diazabicyco octane). Reactions were carried out in the MOPS buffer solution containing 2.5 mM NBT, 10 mM methionine, and 10 μM of cercosporin or ESCs, or 2μM riboflavin, and/or SOD (1mg mL-1) or DABCO (1 mM), and absorbance at 560 nm (A560) measured. Vertical bars represent standard deviation. Means followed by the same letter are not different at judged by Duncan’s multiple range test at P < 0.0001.
56
Figure 2-10. Oxidation of cholesterol by photosensitizers: hematoporphyrin (HP), cercosporin (CR), and elsinochromes (ESCs) under light. Cholesterol (200 mg) was dissolved in pyridine, mixed with photosensitizers with or without β-carotene, as indicated, and incubated for 5 h. The oxidized products were separated by thin-layer chromatography (TLC) with a hexane-isopropanol 9 : 1 (v : v) (A) or 24 : 1 (v : v) (B, C) solvent system. Cholesterol 5α-hydroperoxide (Rf 0.4 or 0.1 in solvent A or B) formed distinct bands after staining with 1 % of N,N-dimethyl-p-phenylenediamine. Radiation of cholesterol to UV light for 24 h resulted in multiple products, but no cholesterol 5α-hydroperoxide (C). Untreated cholesterol (in chloroform) was not visible after staining with the chromogen (C).
57
Figure 2-11. Leakage of electrolytes from illuminated rough lemon leaf discs treated with elsinochromes (ESCs). A) Light increased electrolyte leakage of citrus leaf discs treated with ESC compared with those treated with water or acetone (S) alone at 24 h. B) Increasing electrolyte leakage of rough lemon leaf discs over time after treatment with ESCs in the light. Water, open circles; acetone, closed circles; ESCs, triangles. Data represent the means of two different experiments with five replicates. Vertical bars represent standard deviation. Means followed by the same letter are not different at judged by Duncan’s multiple range test at P < 0.0001.
58
CHAPTER 3 ENVIRONMENTAL FACTORS AFFECTING PRODUCTION OF ELSINOCHROMES BY
Elsinoë fawcettii
Elsinochromes (ESCs), light-activated phytotoxins, are produced by many Elsinoë isolates
and are required for fungal virulence. In this chapter, the effects of environmental factors in
relation to ESC accumulation are investigated. The effects of environmental signals such as light,
pH, medium compositions, carbon and nitrogen sources, ions, and antioxidants on fungal radial
growth and ESC production by E. fawcettii were evaluated. Light and media compositions
influenced ESC production considerably. E. fawcettii produced the highest titers of ESCs on
PDA compared to other media tested. Production of ESCs was stimulated when the fungus was
grown in a medium with ample carbon sources or under nitrogen starvation stress. An increase in
ESC production correlated with an increase in the ambient pH. A reduction in ESC production
was observed when antioxidant agents such as cysteine, DABCO and glutathione, were
exogenously amended into PDA. Ascorbate dramatically enhanced ESC production. Addition of
ions such as CaCl2·2H2O, Ca(NO3)2·4H2O, CoCl2·6H2O, or LiCl decreased ESC production,
whereas other ions tested markedly enhanced ESC production. Production of ESCs was also
affected by the presence of multiple colonies and the distance between two colonies on the same
agar plate, indicating that nutrient competition resulting in nitrogen depletion promoted ESC
production.
Introduction
Elsinoë fawcettii, the causal agent of citrus scab, produces elsinochromes (ESCs) (Liao and
Chung 2008a). ESCs are phytotoxins produced by many species of Elsinoë (Weiss et al. 1987).
ESCs have been investigated as a fungal virulence factor since ESCs produce toxic reactive
oxygen species (ROS) (Liao and Chung 2008a; 2008b).
59
Production and accumulation of secondary metabolites by microbes are often regulated by
a number of environmental and nutritional factors. Physical parameters which affect production
of secondary metabolites include light intensity, temperature, and pH. Nutritional factors such as
carbon source and nitrogen source also affect production of secondary metabolites. Although
significant progress has been made in identifying the environmental factors for production of
fungal secondary metabolites, little is known about their role in ESC production in E. fawcettii.
Light has been demonstrated to be required for ESC biosynthesis and toxicity (Liao and
Chung 2008a; 2008b). ESCs were produced when the fungus was incubated under light and
production was markedly suppressed in the dark. In addition, ESCs having structures similar to
many photosensitizing compounds have been shown to produce reactive oxygen species in a
light-dependent manner (Daub et al. 2005; Liao and Chung 2008b). In Aspergillus species,
production of sterigmatocystin and aflatoxin was regulated by carbon sources (Calvo et al.
2002). Nitrogen sources have diverse effects in regulation of secondary metabolites. For example,
sterigmatocystin and aflatoxin were produced in ammonium-based media (Keller et al. 1997;
Morrice et al. 1998), whereas production of alternariol (AOH) and alternariol monomethyl ether
(AME) by Alternaria alternata (Orvehed et al. 1988) was inhibited by nitrogen. Ambient pH has
been reported to serve as a regulatory of production of many fungal secondary metabolites, such
as aflatoxin, sterigmatocystin, and penicillin (Cotty 1988; Shah et al. 1991; Keller et al. 1997). In
Aspergillus spp., production of fungal secondary metabolites was controlled by complex
regulatory networks involved in the G-protein/c-AMP/protein kinase signaling cascades in
response to environmental factors (Calvo et al. 2002).
Antioxidants, such as butylated hydroxyanisol (BHA) and prophy paraben (PP) have been
shown to inhibit fungal growth and toxin production by Fusarium verticillioides and F.
60
proliferatum (Reynoso et al. 2002; Farnochi et al. 2004). Further, phenolic antioxidants inhibit
ochratoxin A and aflatoxin B production by Aspergillus species (Palumbo et al. 2007; Passone et
al. 2005).
Extrinsic ions are also known to affect toxin production in fungi (Marsh et al. 1975; Cuero
et al. 1988; Jackson et al. 1989). For example, Zn2+, Fe2+, and Cu2+ affect production of
aflatoxins in Aspergillus flavus and zearalenone in Fusarium graminearum (Cuero et al. 2003;
Cuero and Ouellet 2005). Normally, metal ions influence accumulation of fungal toxins via
controlling expression of the genes whose products are required for toxin biosynthesis. In this
study, environmental signals were demonstrated to have multiple effects on ESC production. For
example, co-culturing multiple colonies of E. fawcettii on the same medium tends to trigger early
production of ESCs and the distance between two colonies affects the timing of ESC production.
Materials and Methods
Fungal Strains, Maintenance, and Culture Conditions
The origin of Elsinoë fawcettii Bitancourt & Jenkins (anamorph: Sphaceloma fawcettii
Jenkins) isolate CAL WH-1 and the EfPKS1 null mutants from this isolate used in this study
have been previously described (Chapter 2; Liao and Chung 2008b). Fungi were grown on a
sterilized filter paper, and stored at -20 °C for long-term storage.
The basal media used for fungal growth and toxin production included: potato dextrose
agar (PDA, difco, Becton, Dickinson and Company, Sparks, MD), a complete medium (CM)
containing 1 g Ca (NO3)·4H2O, 0.2g KH2PO4, 0.25g MgSO4·7H2O, 0.15g NaCl, 10g glucose, 1g
each of yeast extract and casein hydrolysate, and 15g agar per liter (Jenns et al. 1989), and a
minimal medium (MM) containing all components of CM but omitting yeast extract and casein
hydrolysate. The pH of media was adjusted by 0.1 M phosphate buffer as described (You et al.
61
2007). Glucose or sodium nitrate in CM medium was substituted with equal molarity of other
appropriate carbon or nitrogen sources.
To prepare fungal inoculum, the 5-day-old mycelium cultured on PDA under continuous
fluorescence light at an intensity of 3.5 J m-2 s-1 was minced with a sterile blender and suspended
in sterilized water. Hyphal suspension (3 µL) was placed on the surface of the test medium (5
mL) in a 60 x 15 mm Petri dish and the plates were incubated under constant light at 25 °C. The
plates were wrapped with aluminum foil for the dark control and incubated under the same
conditions. Fungal growth was determined by colony diameter (millimeters, mm) 3 weeks after
incubation and was measured prior to ESC extraction.
ESC Purification and Quantification
For ESC purification and quantification, four 7-mm diameter agar plugs cut from mycelial
cultures were extracted with 5N KOH in the dark for 16 hr, and the extracts were measured at
480 nm by a model Genesys 5 spectrophotometer (Spectromic Instruments, Rochester, NY). The
ESC concentration was calculated using a molar extinction coefficient of 23,300 (Yamazaki and
Ogawa 1972) and was reported as nano moles per agar plug.
Statistical Analysis
Data were analyzed by ANOVA using SAS (PROCGLM) for PC (SAS Institute Inc., Cary,
N.C.). When differences were significant (P < 0.05), individual treatment means were separated
using Ducan’s Multiple Range Test (P = 0.05). Data are the means of two different experiments
with at least three replicates.
Preparation of Chemicals
Compounds CaCl2·2H2O, Ca(NH3)2·4H2O, LiCl, MgCl2·6H2O, NaCl and KCl were
purchased from Fisher Scientific (Fair Lawn, NJ.), while all other chemicals used in this study
were purchased from Sigma (St. Louis, Mo.). Chemicals were dissolved in water to prepare stock
62
solutions as appropriate. All aqueous solutions were sterilized by filtration. All the chemical
stock solutions were added to solid media. An equal volume of sterile distilled water was added
as the mock control.
Results and Discussion
Fungal Growth and ESC Production in Response to Light, Media Components and pH
As assessed on PDA, E. fawcettii produced high amounts of ESCs under constant light
(Fig. 3-1A). Accumulation of ESCs significantly decreased (P < 0.01%) when the test fungus
was grown under the conditions alternating in a cycle of 12-h light and 12-h dark. ESC
production was almost completely suppressed when the fungus grown under darkness. E.
fawcettii grew slightly faster under light but there was no significant difference between
treatments. The results indicated that light is a critical factor for ESC production. Under constant
light, production of ESCs by the E. fawcettii isolate was highest when the fungus was grown on
PDA and significantly reduced when grown on CM or MM (Fig. 3-1B). Fungal growth was also
concomitantly affected. Minimum medium (MM) has of the same ingredients in CM, except
yeast extract and casein hydrolysate. MM and CM supported equivalent fungal radial growth, but
the fungus produced much less ESCs on CM than on MM, indicating that yeast extract and/or
casein hydrolysate had a negative effect on ESC production.
Effects of pH for fungal growth and ESC production were also tested (Fig. 3-2). A close
correlation between ESC production and pH was observed, i.e., accumulation of ESCs increased
as the pH of medium was elevated (Fig. 3-2). Thus, E. fawcettii alkaline conditions were most
favorable for production of ESCs. By contrast, fungal radial growth was slightly greater under
acidic pH.
63
Carbon Sources on Fungal Growth and ESC Production
As tested on CM, production of ESCs by E. fawcettii was enhanced when glucose was
used as a sole carbon source, in a concentration-dependent manner (Fig. 3-3). Substitution of
glucose with sucrose as the sole carbon source significantly enhanced ESC production, whereas
replacement of glucose with mannitol non-significantly reduced ESC production. Apparently, the
test fungus preferred higher amounts of carbon sources for radial growth and utilized the four
carbon sources equally well.
Carbon sources generally have diverse effects on fungal development and production of
secondary metabolites. Production of aflatoxin by Aspergillus spp. was greatly enhanced when
fungi were cultured in the glucose-containing medium, but not the mannitol-containing medium
(Calvo et al. 2002). However, E. fawcettii can utilize glucose or mannitol efficiently for ESC
production. Given that ESC is synthesized by a polyketide pathway, likely by condensation of
acetyl-CoA and malonyl-CoA (Liao and Chung 2008b), one would expect that high
concentration of carbon sources enhances the acetyl-CoA pool via glycolysis, and thus, boost the
ESC biosynthesis.
Effects of Inorganic and Organic Nitrogen on Fungal Growth and ESC Production
To determine if ESC production is affected by nitrogen sources, sodium nitrate in MM was
substituted with ammonium chloride, ammonium nitrate, glutamine, or glycine at various
concentrations as the sole nitrogen source and ESC production was measured. Ammonium
chloride and ammonium nitrate suppressed ESC production but only slightly affected fungal
radial growth (Fig. 3-4A). At higher concentration (4g L-1) of ammonium chloride and
ammonium nitrate, production of ESCs was inhibited completely. ESC production was inhibited
when glutamine but not glycine was used as the sole nitrogen source even though fungal growth
was slightly stimulated (Fig. 3-4B). In a prior study, expression of the EfPKS1 gene has been
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shown to be regulated by carbon/nitrogen sources and pH (Liao and Chung 2008b). In addition,
several binding elements that are recognized and bound by global transcription factors for
specific gene expression, such as C/EBP (cAMP-inducible genes), AreA (nitrogen or light
regulatory genes), WC1/WC2 (light regulatory genes) and PacC (pH responsive genes), were
found in the promoter region of the EfPKS1 gene, suggesting that environmental signals affected
ESC production via transcriptional activation of the ESC biosynthetic genes.
Effects of Antioxidants on Fungal Growth and ESC Production
Since ESCs generate reactive oxygen species in aerobic conditions upon exposure to light
(Liao and Chung 2008a), experiments were also performed to test if antioxidants such as
ascorbate, cysteine, DABCO, and reduced glutathione influence ESC production and fungal
growth. As tested on MM, addition of cysteine, DABCO, or reduced glutathione at higher
concentration (cysteine at 50 mM, each of DABCO and glutathione at 10 mM) inhibited ESC
production substantially (Fig. 3-5). Cysteine at 100 mM and DABCO at 50 mM completely
inhibited fungal growth. By contrast, addition of ascorbate into MM promoted both fungal
growth and ESC production in a dose-dependent manner (Fig. 3-5). Those antioxidants often
inactivate reactive oxygen species (ROS) and have been previously shown to alleviate the
cellular toxicity of ESCs (Liao and Chung 2008a). This study showed that the antioxidants might
interfere with biosynthesis of ESCs. By contrast, ascorbate, which has been reported to reduce
O2 to H2O2 or to scavenge H2O2 from generating ·OH (hydroxyl radicals) in planta (Fry 1998),
enhanced both fungal growth and ESC production in this study. However, it is unknown how the
antioxidants inhibit or promote ESC production and fungal growth.
Effects of Ions on ESC Production
Addition of CaCl2, Ca(NO3)2·4H2O, CoCl2, or LiCl into PDA decreased ESC production
by E. fawcettii (Fig. 3-6). Metal ions CoCl2 at 10 mM and LiCl at 100 mM suppressed fungal
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radial growth. Addition of CuCl2, FeCl3, KCl, MgCl2, MnCl2, NaCl, or ZnCl2 into PDA elevated
ESC production to various levels, depending on the concentration of the compound tested (Table
3-1). Addition of EGTA, the Ca2+ chelator, enhanced ESC production. Similar inhibitory or
stimulatory effects of ions in PDA were also observed when fungus was cultured in CM (Table
B-1).
Co-culturing Enhances ESC Production
As described above, production of ESCs was influenced by diverse environmental factors.
The stimulatory effect of physical interactions between fungal colonies for ESC production was
observed. When a single colony of E. fawcettii was placed in the center of PDA medium,
accumulation of small amounts of ESCs was observed 10 days after inoculation and
continuously increased as duration of incubation increased (Fig. 3-7A). When three or five spots
(each was separated by 1-cm apart) were inoculated with the same E. fawcettii isolate on a PDA
plate, the rate for ESC production by each inoculated colony was much faster and the magnitude
of ESC accumulation was much higher as visually indicated by red pigment compared to those
produced by a single colony inoculated alone (Fig. 3-7A). Interestingly, ESCs secreted by each
of the colonies tended to diffuse toward one another in medium (Fig. 3-7B). Similar phenomena
were also observed in a distance-response manner when a wild-type isolate was co-cultured with
the EfPKS1 null mutants, producing no ESCs (Fig. 3-7C). It is likely that competition for
nutrients, particularly nitrogen source, promoted early production of ESCs.
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Table 3-1. Effects of ions and EGTA on ESC production by Elsinoë fawcettii Treatment Conc. (mM) Mean colony dai.
(mm) ± SEM ESCs (nmoles per plug), mean ± SEM
none - 13.5 ± 0.4 14.9 ± 3.3 CuCl2·2H2O 0.1 14.0 ± 0.3 25.12 ± 5.80 1.0 13.5 ± 0.9 27.18 ± 2.18 10.0 0.0 ± 0.0 nd1 FeCl3 0.1 14.6 ± 0.4 23.3 ± 3.0 0.2 15.1 ± 0.5 17.8 ± 4.0 0.5 15.3 ±1.4 22.3 ± 2.9 1.0 16.0 ± 0.8 26.0 ± 1.8 2.0 14.3 ± 0.5 34.8 ± 2.7 10.0 0.0 ± 0.0 nd KCl 50.0 12.5 ± 0.8 32.8 ± 5.2 100.0 11.9 ± 0.5 24.5 ± 7.6 MgCl2·6H2O 50.0 13.1 ± 0.5 36.5 ± 7.5 100.0 12.3 ± 0.3 45.7 ± 6.2 MnCl2·4H2O 0.2 14.1 ± 0.3 14.7 ± 2.8 1.0 12.0 ± 0.4 13.9 ± 4.3 5.0 12.2 ± 0.6 24.9 ± 3.2 10.0 5.1 ± 0.3 20.5 ± 4.5 100.0 0.0 ± 0.0 nd NaCl 50.0 12.6. ± 0.5 15.2 ± 6.9 100.0 12.4 ± 0.2 30.4 ± 5.4 ZnCl2 0.1 13.5 ± 0.4 19.9 ± 6.9 1.0 13.8 ± 0.6 19.6 ± 3.6 10.0 0.0 ± 0.0 nd EGTA 1.0 13.2 ± 0.1 22.6 ± 3.4 2.0 9.3 ± 0.9 17.6 ± 2.2 3.0 8.8 ± 0.8 19.2 ± 1.0
1nd, not determined
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Figure 3-1. Effects of light (A) and medium compositions (B) on fungal growth and
elsinochrome (ESC) production by E. fawcettii. Insets indicate radial growth of fungal colonies which were measured before ESC extraction. A) Fungal cultures grown on PDA were incubated at 25 °C under constant light, in complete darkness or 12-h light/dark alternation for 21 days. B) E. fawcettii was cultured on PDA, CM, or MM, and incubated under constant light for 21 days. ESC was extracted with KOH and measured at A480 nm. Vertical bars represent standard deviation. Means followed by the same letter are not different at judged by Duncan’s multiple range test at P < 0.0001.
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Figure 3-2. ESC accumulation and growth of E. fawcettii at different pH on MM. Insets indicate the diameters of fungal colonies under the appropriate conditions. pH was adjusted to 4 with sodium phosphate buffer (0.1M) buffer and 5N HCl. Vertical bars represent standard deviation. Means followed by the same letter are not different at judged by Duncan’s multiple range test at P < 0.0001.
69
Figure 3-3. Effects of various carbon sources on fungal growth and ESC production by E. fawcettii assayed on CM medium. Insets indicate the diameters of fungal colonies under the appropriate conditions. Different concentration of glucose, mannitol, sorbitol, and sucrose were used to substitute glucose as the sole carbon source in the CM medium. Vertical bars represent standard deviation. Means followed by the same letter are not different at judged by Duncan’s multiple range test at P < 0.0001.
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Figure 3-4. Effects of nitrogen sources on fungal growth and ESC production by E. fawcettii
assayed in MM medium. A) Ammonium chloride and ammonium nitrate suppressed ESC production. B) ESC production was inhibited when glutamine but not glycine was used as the sole nitrogen source. Insets indicate the diameters of fungal colonies under the appropriate conditions for 21 days. Vertical bars represent standard deviation. Means followed by the same letter are not different at judged by Duncan’s multiple range test at P < 0.001.
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Figure 3-5. Effects of antioxidatants, A) cysteine, B) DABCO (1,4-diazabicyco octane), C)
glutathione, and D) ascorbate on ESC production by E. fawcettii in MM medium. Insets indicate the diameters of fungal colonies under the appropriate conditions for 21 days. Vertical bars represent standard deviation. Means followed by the same letter are not different at judged by Duncan’s multiple range test at P < 0.001.
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Figure 3-6. Inhibition of ESC production by Ca2+, Co2+, and Li2+ in E. fawcettii. Insets indicate
the diameters of fungal colonies under the appropriate conditions. In A, C, and D, the fungus was grown on PDA medium either in the absence or presence of different concentration of ions. B) Fungus was grown at MM medium with (+) or without (-) the component of Ca(NO3)2·4H2O. Vertical bars represent standard deviation. Means followed by the same letter are not different at judged by Duncan’s multiple range test at P < 0.01.
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Figure 3-7. Effects of the number of fungal colonies and the distances on ESC production by E. fawcettii. Mycelial suspensions were place on PDA with different numbers and distances and incubated under constant light. A) Production and diffusion of ESCs were observed 10 (A-1) and 15 (A-2) days after incubation. B) Production of ESCs on PDA was promoted when three colonies of E. fawcettii were inoculated with 1cm apart between each and incubated for 9 to 17 days. The arrows indicate the red-pigment started to accumulate in the side of colonies that are close to another colony in 9- and 10-day-old cultures. C) The EfPKS1 mutants [Red arrows, D3; blue arrows, D4 (Liao and Chung 2008b)] were inoculated around the wild type, showing similar stimulation on ESC production and diffusion from wild type colonies (1, 2, 3, 4) 15 days post-incubation.
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CHAPTER 4 GENETIC DISSECTION DEFINES THE ROLES OF ELSINOCHROME PHYTOTOXIN FOR
FUNGAL PATHOGENESIS AND CONIDIATION OF THE CITRUS PATHOGEN Elsinoë fawcettii
Elsinochrome pigments produced by many phytopathogenic Elsinoë species are non-host
selective toxins which react with oxygen molecules after light activation to produce highly toxic
reactive oxygen species. This chapter describes the cloning, expression, and functional
characterization of the polyketide synthase-encoding gene, EfPKS1, which is required for the
production of elsinochromes (ESCs) and fungal pathogenesis. Target disruption of EfPKS1 in E.
fawcettii completely abrogated ESC production, drastically reduced conidiation, and
significantly decreased lesion formation on rough lemon leaves. All mutant phenotypes were
restored to the wild type in fungal strains expressing a functional copy of EfPKS1. Accumulation
of the EfPKS1 transcript and ESCs by a wild-type strain appears to be coordinately regulated by
light, nutrients, and pH. The results clearly indicate that the product of EfPKS1 is involved in the
biosynthesis of ESCs via a fungal polyketide pathway, and that ESCs play an important role in
fungal pathogenesis.
Introduction
Many phytopathogenic fungi produce perylenequinone pigments, which are light-activated
and nonhost-selective phytotoxins (Daub et al. 2005). For example, the compounds, alteichin,
altertoxin, alterlosin, and stemphyltoxin are produced by Alternaria spp. (Stack et al. 1986;
Davis and Stack 1991) and Stemphylium botryosum (Davis and Stack 1991); cercosporin and
isocercosporin are produced by many Cercospora spp. (Daub et al. 2005); ESCs are produced by
many Elsinoë and Sphaceloma spp. (Weiss et al. 1987; Liao and Chung 2008a); hypomycin A is
produced by Hypomyces spp. (Liu et al. 2001); hypocrellin is produced by Hypocrella bambusae
(Weiss et al. 1987); Shiraia bambusicola (Wu et al. 1989), and phleichrome, calphostin C,
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cladochrome, and ent-isophleichrome are produced by Cladosporium spp. (Weiss et al. 1987;
Arnone et al. 1988). Among all phytotoxins identified, perylenequinone toxins are unique
because they contain a chromophore of phenolic quinine that absorbs light energy
(photosensitizers) and produces reactive oxygen species (ROS) such as the hydroxyl radical
(OH•), superoxide (O2•-), hydrogen peroxide (H2O2), and singlet oxygen (1O2) (Daub and
Ehrenshaft 2000; Daub et al. 2005). Although the biological functions of the light-activated
perylenequinone toxins for the producing fungi remain largely unknown, their production by a
wide range of plant pathogens suggests an important role for these toxins in fungal pathogenesis
(Daub and Ehrenshaft, 2000). Perylenequinone toxins were originally investigated because of
their possible pharmaceutical application (Hudson and Towers 1991) or because of their
potential as food contaminants (Stack et al. 1986). In contrast, the role of perylenequinone toxins
in fungal pathogenesis has been investigated very little compared to many other host-specific
phytotoxins. Only the role of cercosporin in Cercospora diseases has been demonstrated
genetically (Upchurch et al. 1991; Callahan et al. 1999; Shim and Dunkle 2003; Choquer et al.
2005; Choquer et al. 2007; Dekkers et al. 2007).
ESCs are red/orange pigments produced by a number of phytopathogenic Elsinoë species.
ESCs comprise of at least four derivatives (A, B, C, and D) with a common perylenequinone
backbone but differing in side groups (Weiss et al. 1987). The bright red pigments, elsinochrome
A, B, and C were originally isolated from cultures of a pecan pathogen, Elsinoë randii
(anamorph: Sphaceloma randii). Elsinochrome D is likely derived from elsinochrome C by
formation of a methylenedioxy ring. Elsinoë fawcettii infects lemons, grapefruit, and some
tangerines and their hybrids, producing exterior blemishes (citrus scab) on the fruit, which is a
serious problem for the fresh-fruit market worldwide. In the previous studies, elsinochrome
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pigments were extracted from a field isolate of E. fawcettii and the production of 1O2 and O2 •- by
ESCs upon exposure to light was demonstrated (Chapter 2; Liao and Chung 2008a). Crude
extracts containing a mixture of five elsinochrome derivatives from E. fawcettii cultures were
shown to be highly toxic to citrus and tobacco cells in suspension culture, and induced
electrolyte leakage of host leaves. The toxicity of ESCs was reduced considerably when 1O2
quenchers such as bixin, ascorbate, and reduced glutathione were present. Furthermore, ESCs
induced necrosis on rough lemon leaves when exposed to visible light, and the development of
necrosis was reduced by co-applying 1O2 quenchers (Liao and Chung 2008a). Thus ESCs
function as photosensitizing compounds that are toxic to plant cells by generating 1O2 and O2 •-.
Discovery of ESCs’ toxicity to the plants led to studies of the role of ESCs in fungal
pathogenesis and the molecular mechanisms leading to its biosynthesis. ESCs were implicated as
the polyketide-derived based on their structural similarity with several perylenequinones.
However, no direct evidence of this structural of ESCs has been established. This chapter
describes the cloning, coordinate expression, and functional characterization of the polyketide
synthase-encoding gene, EfPKS1, for the production of ESCs. This was demonstrated by creating
and analyzing loss-of-function EfPKS1 mutants of E. fawcettii. The results indicate that ESCs are
required for fungal pathogenesis.
Materials and Methods
Fungal Isolate and Growth Conditions
The wild type CAL WH-1 isolate that was single-spore isolated from scab affected
calamondin (Citrus madurensis Lour) fruit has been previously characterized (Liao and Chung
2008a; Chapter 2 and 3) and was used as the recipient host for transformation and targeted gene
disruption. This isolate was routinely maintained on potato dextrose agar (PDA, Difco, Sparks,
MD). For toxin production, fungal mycelia were mincing with a sterile blender, spread on media
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and incubated under continuous fluorescent light for 5 or 7 days at room temperature (~25 °C).
For generation of protoplasts, fungal isolates were grown in 50 mL of potato dextrose broth
(PDB, Difco) for 7 days, minced, and mixed with fresh PDB (200 mL), and incubated for
additional 15 h. Fungal cultures used for DNA or RNA isolation were grown on media with a
layer of sterile cellophane as previously described (Choquer et al. 2005). Complete medium
(CM), minimal medium (MM), and protoplast regeneration medium (RMM) used in this study
have been described in Chapter 3 and/or elsewhere (Jenns et al. 1989; Chung et al. 2002). The
pH of media was adjusted by 0.1 M phosphate buffer as previously described (You et al. 2007).
Extraction and Analysis of ESC Toxins
Isolation of fungal toxins from culture and TLC analysis are described in chapter 2.
Screening of ESC-deficient mutants was conducted on thin PDA as previously described
(Choquer et al. 2005; Chen et al. 2007).
Molecular Cloning and Analysis of the EfPKS1 Gene
Two degenerate oligonucleotides LCKS1 (5’-GTNCCNGTNCCRTGCATYTC-3’) and
LCKS2 (5’-GAYCCNMGNTTYTTYAAYATG-3’) that are complementary to the conserved β-
keto synthase (KS) domain of fungal type-I polyketide synthase genes (Bingle et al. 1999) were
synthesized and used for amplification from E. fawcettii genomic DNA using Taq DNA
polymerase (GenScript, Piscataway, NJ). The amplified DNA fragment (~700 bp) was cloned
into pGEM-T easy vector (Promega, Madison, WI) for sequencing analysis from both directions
at Eton Bioscience (San Diego, CA). Sequences were blasted against the databases at the
National Center for Biotechnology Information (NCBI) using the BLAST network service
(Altschul et al. 1997) to determine the similarity of the amplified fragment. The full-length
EfPKS1 gene was obtained by PCR using a chromosome walking strategy as described
previously (Chen et al. 2005; You et al. 2007) and by PCR with two inverse primers (Table C-1;
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Fig. C-1) (Choquer et al. 2005). A chromosome library of E. fawcettii was prepared from
genomic DNA cleaved with four different enzymes (EcoRV, PvuII, SmaI and StuI), and ligated
to the adaptors from the Universal Genome Walker kit following the manufacturer’s instructions
(BD Biosciences, San Jose, CA). To walk upstream and downstream into unknown genomic
regions, primer were synthesized to complement the known regions and used for multiple rounds
of PCR amplification with adaptor primers supplied with the kit. For PCR with inverse primers,
fungal DNA was digested with restriction endonucleases, self-ligated, and used as a template for
amplification. Oligonucleotide primers used for PCR amplification and sequence analysis were
synthesized by Integrated DNA Technologies (Coralville, IA), Allele Biotechnology and
Pharmaceuticals (San Diego, CA), respectively. Open reading frame (ORF) and exon/intron
positions were predicted using the Softberry gene finding software and confirmed by
comparisons of genomic and cDNA sequences. Functional domains were predicted according to
the PROSITE database using ExPASy (Gasteiger et al. 2003) or Motif/ProDom and Block
programs (Henikoff et al. 2000). Analysis of the promoter region was conducted using regulatory
sequence analysis tools (van Helden 2003).
Targeted Gene Disruption
To disrupt the EfPKS1 gene in E. fawcettii, a 5.8-kb DNA fragment encompassing the
EfPKS1 ORF was obtained by PCR with primers efup3 (5’-
CAATTACGCGAATGGGTCACAGAGC-3’) and efdown11 (5’-
CGTCAAGGACATCAGCGAGTC-3’). The amplified DNA fragment was purified with a DNA
purification kit (Mo Bio Laboratories, Carlsbad, CA), and cloned into pGEM-T easy vector to
create pSPKS0311. A 1.3-kb EcoRV-KpnI DNA fragment, corresponding to the conserved acyl
transferase (AT) domain of EfPKS1, was removed and replaced with an end-filled 2.1-kb
fragment harboring the hygromycin phosphotransferase B gene (HYG) cassette under the control
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of the Aspergillus nidulans trpC gene promoter from pUCATPH (Lu et al., 1994) to yield the
disruption construct, pPKS0311 (Fig. 4-4A). A split marker strategy was used to enhance the
efficiency of double crossing-over recombination as previously described (Choquer et al. 2005).
A 4.6-kb DNA fragment containing truncated 5’ EfPKS1 fused with 3’ HYG and a 3.3-kb
fragment encompassing 3’ EfPKS1 joined with 5’ HYG were amplified, respectively, with
primers efup3/hyg1 (5’-AGGAGGGCGTGGATATGTCCTGCGGG-3’) and efdown11/hyg2
(5’-CCGACAGTCCCGGCTCCGGATCGG-3’) from pPKS0311 using the Takara Ex Tar PCR
system (Takara Bio USA, Madison, WI). Fungal protoplasts were prepared by the method of
Chung et al. (2002) except that hyphae were incubated with cell wall degrading enzyme cocktails
for 6 h instead of 2 h. The resulting DNA fragments were mixed and transformed into protoplasts
(1 x 105) of wild type using CaCl2 and polyethylene glycol as previously described (Chung et al.
2002). The two hybrid fragments share 400-bp of overlapping sequence within the HYG gene.
The HYG gene is not functional unless recombination occurs between the two truncated HYG
DNA fragments. Fungal transformants appearing on RMM medium supplementing with 200 µg
mL-1 hygromycin (Roche Applied Science, Indianapolis, IN) after 2 to 3 weeks were selected
and tested for lack of ESC production (red/orange pigments) on thin PDA.
Genetic Complementation
For genetic complementation, a DNA fragment (8.4 kb) including the entire EfPKS1 ORF
and its endogenous promoter was amplified from genomic DNA with primers efup3 and efdown
18 (5’-CTTTCGTCGTCGGCCCAAC-3’) by an Expand High Fidelity PCR system (Roche
Applied Science) and co-transformed with plasmid pBarKS1 carrying a phosphinothrin
acetyltransferase gene responsible for bialaphos resistance under control of the A. nidulans trpC
promoter (Pall and Brunelli 1993) into an EfPKS1 disruptant (D4). Transformants were selected
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against 100 μg mL-1 of DL-phosphinothricin (chlorimuron ethyl; Chem Service, West Chester,
PA) and tested for restoration of ESC production.
Miscellaneous Methods of Processing Nucleic Acids
Fungal DNA was isolated with a DNeasy Plant kit (Qiagen, Valencia, CA). Standard
procedures were used for endonuclease digestion of DNA, electrophoresis, and Southern-and
Northern-blot hybridizations. Plasmid DNA was purified using a Wizard DNA purification kit
(Promega) from transformed Escherichia coli DH5α bacterial cells. Fungal RNA was extracted
with Trizol reagent (Invitrogen, Carlsbad, CA). Double stranded cDNA of EfPKS1 was
synthesized with a cDNA synthesis kit (BD Biosciences) following the manufacturer’s
instructions and amplified with gene-specific primers. The amplified fragments were purified
and directly subjected to sequence analysis. DNA probes used for hybridization were labeled
with digoxigenin (DIG)-11-dUTP (Roche Applied Science) by PCR with gene-specific primers.
The manufacturer’s recommendations were followed for probe labeling, hybridization, post-
hybridization washing and immunological detection of the probe using a CSPD
chemofluorescent substrate for alkaline phosphatase (Roche Applied Science).
Preparation of Fungal Inoculum and Pathogenicity Assays
Assays for fungal pathogenicity were conducted on detached rough lemon (Citrus jambhiri
Lush) leaves inoculated with conidial suspension or agar plugs covered with fungal hyphae.
Rough lemon is susceptible to all Elsinoë pathotypes of citrus (Timmer et al. 1996). Conidia
were prepared as described by Timmer and colleagues (1996) with modifications. Briefly, fungal
hyphae were minced in Fries medium (Fries 1978), placed on Petri dish (15 x 90 mm), and
incubated for 2 to 3 days in the dark to trigger conidial formation. Rough lemon seedlings were
maintained in a greenhouse and expanding immature leaves of approximately 13-20 mm length
and 4-7 mm width were collected for pathogenicity assays. A conidial suspension (2 μL, 1 x 105
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mL-1) was carefully placed on the leaves and the inoculated leaves were incubated in a moist
chamber under constant fluorescence light for lesion formation. Pathogenicity also was evaluated
using agar plugs. Briefly, PDA agar plugs (4 mm in diameter) were cut from mycelial mats
cultured on PDA for 7 days and placed on the underside of rough lemon leaves (~12 days after
emergence). The inoculated leaves were incubated in a mist chamber and examined for lesion
formation daily.
Results
Cloning and Characterization of EfPKS1 Gene
A 0.7-kb DNA fragment was amplified from genomic DNA of E. fawcettii with degenerate
primers designed to anneal to the conserved β-keto-synthase (KS) domains of many type-I fungal
polyketide synthases. Sequence analysis revealed that the amplified fragment has strong
similarity to the KS of PKSs. The gene was named EfPKS1 (E. fawcettii polyketide synthase
gene 1). Subsequently, the entire EfPKS1 ORF sequences as well as its 5’ and 3’ nontranslated
regions were obtained by multiple rounds of PCR from chromosome walking library or with two
inverse primers from restriction enzyme-digested and self-ligated DNA pools. As a result, over 8
kb of genomic sequences were obtained, assembled, and deposited within EMBL/GenBank Data
Libraries under accession number EU086466.
Computer prediction and comparison between cDNA and genomic DNA sequences
revealed that EfPKS1 contains two exons interrupted by a 52-bp intron near the 5’ end of EfPKS1
(data not shown). The intron has characteristic splicing (5’-/gt---ag/-3’) and internal lariat
(cta/gat/c) consensus sequences often found in genes of filamentous fungi. Conceptual
translation revealed that EfPKS1 encodes a polypeptide containing 2192 amino acids that
displays considerable similarity and identity to numerous type-I PKSs of fungi, particularly those
involved in pigment formation and biosynthesis of secondary metabolites (Fig. 4-1). Similar to
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many fungal type-I PKSs, the translated product of EfPKS1 has a β-keto-synthase (KS) domain,
an acyltransferase (AT) domain, two acyl carrier protein (ACP) domains, and a
thioesterase/claisen cyclase (TE/CYC) domain (Fig. 4-1A). Phylogenetic relationships of
EfPKS1 to other fungal polyketide synthases, inferred from the conserved KS or AT domain,
revealed that EfPKS1 is highly similar to the fungal non-reducing PKSs, including those
involved in the biosynthesis of melanin, cercosporin, bikaverin, sirodesmin, aflatoxin, and other
pigments (Fig. 4-1B and C).
Promoter Analysis of EfPKS1 Gene
To gain a better understanding in the regulation of EfPKS1 gene expression, I analyzed
1.1-kb sequences upstream of the putative ATG translational start codon of EfPKS1 and
identified several putative binding sites for diverse transcriptional regulators (Fig. 4-2). A TATA
box-like sequence (TATATC) on the sense strand was identified 264 bp upstream from the ATG
codon. The promoter region of EfPKS1 has multiple GATA consensus motifs, potential binding
sites for the nitrogen-induced AreA (Marzluf 1997) and the light-regulated WC1/WC2 (Linden
et al. 1997) transcriptional activators. The EfPKS1 promoter contains four ambient pH-regulated
PacC-binding consensus motifs (GCCARG; Espeso et al. 1997) and multiple cAMP-inducible
C/EBP-binding motifs (CCAAT or CAAT; Rangan et al. 1996). In addition, EfPKS1 promoter
contains three MRAGGGR and two CATTCY consensus motifs that have been shown to serve
as binding sites for the conidial formation-related BrlA and AbaA transcriptional activators in A.
nidulans (Adams et al. 1998). Analysis of the complementary strand of the EfPKS1 promoter
also identified multiple AreA, WC complex, PacC, C/EBP, and BrlA binding motifs (Fig. 4-2).
Expression and Regulation of EfPKS1 Gene and ESC Production
To determine the factors affecting ESC production and expression of the EfPKS1 gene,
fungal cultures were grown on media with different carbon, nitrogen sources, pH values, or
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incubated in the light or complete darkness. ESCs were extracted and analyzed by
spectrophotometry and total RNA was extracted and analyzed by Northern-blot hybridization. A
time-course analysis of EfPKS1 RNA levels and ESC production revealed that the EfPKS1 gene
transcript accumulated to a detectable level by day 3 and was elevated by days 4 and 5 (Fig. 4-
3A). Similarly, ESCs were detected at low concentration at days 3 and 4, yet accumulated
rapidly to high levels at day 5. Accumulation of EfPKS1 transcript and ESCs was much higher
when fungal cultures were incubated under continuous light compared to those grown in the dark
(Fig. 4-3B). The EfPKS1 gene was preferentially expressed and ESCs accumulated to high levels
when E. fawcettii was cultured in glucose-rich medium under illumination (Fig. 4-3C). By
contrast, ammonium nitrate deprivation stimulated the accumulation of both the EfPKS1
transcript and ESCs (Fig. 4-3D). Both expression of EfPKS1 and production of ESCs were
favored when the fungus was grown under alkaline conditions (Fig. 4-3E).
EfPKS1 is Required for ESC Production
The function of EfPKS1 in relation to ESC production was determined by targeted gene
disruption in E. fawcettii. A disruption plasmid (pPKS0311) carrying the hygromycin
phosphotransferase B gene (HYG) cassette flanked by truncated EfPKS1 sequences on each side
was constructed. Two separate DNA fragments overlapping within the HYG gene (Fig. 4-4A)
were amplified and directly transformed into the wild type E. fawcettii for targeted gene
disruption. In total, 600 transformants were recovered from media containing hygromycin.
Among them, approximately 100 transformants failed to accumulate the red/orange pigments on
PDA after 30-days of incubation under constant light and were considered putative EfPKS1
mutants. Southern-blot analysis of genomic DNA isolated from 13 putative EfPKS1 mutants
revealed that all transformants tested were missing the expected 3.5-kb hybridizing band of the
wild-type locus, when fungal DNA was cleaved with restriction endonuclease ClaI, and
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hybridized to probe I that recognizes sequences in the 5’ end of EfPKS1 (Fig. 4-4B and data not
shown). All 13 transformants displayed a 5.1-kb hybridizing band as a result of HYG insertion
within EfPKS1. Four mutants had a single 5.1-kb hybridizing band (Fig. 4-4B), whereas the other
nine mutants displayed additional hybridizing signals larger or smaller than 5.1 kb (data not
shown), likely resulting from ectopic insertions. When fungal genomic DNA was cleaved with
XbaI and hybridized to probe II that recognizes the 3’ end sequences of EfPKS1, an expected
7.9-kb band was detected in wild type (Fig. 4-4C). By contrast, all 13 transformants had a single
4.6-kb hybridizing band resulting from the HYG insertion at EfPKS1 locus (Fig. 4-4C and data
not shown). The hybridizing profiles obtained from Southern-blot analysis with two different
probes indicated that EfPKS1 of each transformant was replaced with the HYG gene cassette via
homologous integration.
Successful disruption of EfPKS1 was confirmed by Northern-blot analysis (Fig. 4-5A). The
DNA probe (probe 3, Fig.4-4A) hybridized to total RNA of wild type displays a 6.6-kb
hybridizing signal. However, the probe failed to detect the EfPKS1 transcript in three randomly
selected mutants, indicting that they are EfPKS1 null mutants. Quantitative assays of ESC
production by the EfPKS1 null mutants after KOH extraction revealed that the null mutants did
not accumulate measurable ESCs compared to wild type (Fig. 4-5B). No ESCs were detected
from the acetone extracts of four null mutants on TLC, indicating the disruption of EfPKS1
completely obliterated ESC production (Fig. 4-5C).
Genetic complementation experiments revealed that the ESC-deficient phenotype of a null
mutant (D4) was reverted by acquiring and expressing a functional EfPKS1 gene with its
endogenous promoter (Fig. 4-5C), confirming the requirement for EfPKS1 in ESC production in
E. fawcettii.
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Disruption of EfPKS1 Reduces Conidiation
The EfPKS1 null mutants displayed normal radial growth comparable to wild type, yet
produced far fewer conidia relative to wild type (Table 4-1). Genetic complementation by
introducing a functional copy of EfPKS1 gene into protoplasts of D4 null mutant, resulted in two
transformants with restored conidial production (Table 4-1), indicating a close link between
EfPKS1 function and conidiation.
The EfPKS1 Gene is Required for Full Virulence
Since the EfPKS1 null mutants were severely defective in conidial production, fungal
pathogenicity was first evaluated on detached rough lemon leaves inoculated with agar plugs cut
from fungal mycelium (without conidia). As shown in Fig. 4-6, inoculation of wild type and two
genetically reverted strains (C1 and C2) resulted in pink to light brown scab lesions with round
pustules around the edges, whereas the EfPKS1 null mutants did not incite any visible lesions.
Quantitative assays indicated that over 65% of the sites inoculated with agar plugs from the
cultures of wild type or the complementation strains developed necrotic lesions (Table 4-1). By
contrast, none of the sites inoculated with EfPKS1 null mutants or agar plugs alone produced
visible necrosis.
Pathogenicity assays also were performed on detached leaves inoculated with conidial
suspension. In this assay, only the D4 null mutant was evaluated for pathogenicity because the
other null mutants produced very few conidia. When assayed on young leaves (approximately 3
days after emergence), D4 mutant induced necrotic lesions at rates and magnitudes
indistinguishable from those induced by wild type and the C2 strain genetically expressing a
functional EfPKS1 (Fig. 4-7A). Wild type and the C2 strain produced characteristic scab lesions
when inoculated onto older leaves (~7 days after emergence), whereas the D4 null mutant with
similar amounts of conidia (1 x 105 mL-1) incited fewer and smaller lesions presumably due to
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lack of the production of ESCs (Fig. 4-7B). Nevertheless, disruption of EfPKS1 yielded mutants
that were completely devoid of ESC production and defective in conidiation and scab lesion
formation, indicating that ESCs are a determinant of fungal virulence in E. fawcettii.
Discussion
ESCs, produced by many phytopathogenic fungi of the Elsinoë genus, consist of at least
four derivatives differing mainly in their side groups. In the present study, the fungal EfPKS1
gene was demonstrated to be required for ESC biosynthesis, and thereby ESCs were conclusively
shown to play a role in fungal virulence. The results also indicate that ESCs are synthesized via a
fungal polyketide pathway.
As with many type-I fungal polyketide synthases (Kroken et al. 2003; Choquer et al. 2005;
Keller et al. 2005), the EfPKS1 product contains five functional domains, including a KS, an AT,
a TE/CYC, and two ACP domains, which are involved in catalyzing iterative condensations of
acetates and malonates, and chain elongation and cyclization of polyketomethylenes (Watanabe
and Ebizuka 2004). EfPKS1 also has a conserved cysteine residue in the KS domain and
conserved serine residues in the AT, ACP, and TE/CYC domains, similar to other fungal PKSs
belonging to the non-reducing group (Kroken et al. 2003). Integration of a hygromycin-
resistance gene cassette specifically at the EfPKS1 locus resulted in fungal mutants that were
completely devoid of ESC production, severely defective in sporulation, and delayed in lesion
development on older rough lemon leaves. The mutant phenotypes were fully complemented in a
strain that genetically acquired and functionally expressed EfPKS1, confirming that mutation of
EfPKS1 is responsible for the observed deficiencies and that ESCs are important virulence
factors. Pathogenicity assays on detached rough lemon leaves revealed that E. fawcettii incites
more severe necrotic lesions when inoculated with conidial inoculation compared to mycelium
cut from agar plugs. Although the EfPKS1 null mutants were also defective in conidial formation,
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reduction of fungal virulence was mainly attributed to the impairment of ESC production rather
than conidial formation and germination. When pathogenicity was evaluated with conidial
suspension, the D4 null mutant induced scab lesions on young leaves (3 days after emergence),
comparable to those induced by the wild type. Hence, the EfPKS1 null mutant was apparently
not deficient in conidial germination. However, the D4 null mutant induced fewer lesions on
older leaves (7 days after emergence) strongly indicating that production of ESCs in essential for
full virulence of E. fawcettii.
Expression of the EfPKS1 gene was correlated with accumulation of ESCs. The EfPKS1
transcript and ESCs accumulated to high levels when the fungus was grown in the light, in the
presence of higher amounts of glucose, at alkaline pH, or in the absence of a nitrogen source.
Differential expression of EfPKS1 in response to various environmental conditions was further
supported by analyzing the promoter region for putative DNA binding sites for global
transcriptional activators. For example, two GATA consensus sites, presumably involved in the
binding of the AreA/Nit2 nitrogen regulatory proteins (Marzluf 1997) and/or the WC1/WC2
light responsive transcriptional regulators (Linden et al. 1997) were identified. The promoter
region of EfPKS1 has three consensus GCCARG motifs that are likely involved in the binding of
the pH-responsive transcriptional regulator, PacC (Espeso et al. 1997). The EfPKS1 promoter
also has multiple CCAAT or CAAT consensus motifs involved in binding cAMP-activated
proteins such as CCAAT/enhancer-binding protein (C/EBP) (Ramji and Foka 2002).
In addition to complete abrogation of ESC production, EfPKS1 null mutants also were
severely defective in conidial production. The ESC-producing phenotype and conidiation were
fully restored by expressing a dominant-activated allele of an E. fawcettii EfPKS1 protein in a
null mutant. These findings indicate a tight connection between ESC biosynthesis and
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conidiation. It has long been known that production of natural compounds by microorganisms is
often linked with cell development and/or differentiation (reviewed in Adams and Yu 1998;
Calvo et al. 2002; Yu and Keller 2005; Brodhagen and Keller 2006). It appears that both
conidiation and production of secondary metabolites in fungi respond to common environmental
cues, subsequently trigger signaling transduction pathways, and regulate gene expression inside
the cells. It is well known that environmental factors such as light, the types of carbon and
nitrogen sources, and ambient pH via a PacC-mediated pathway regulate both developmental
differentiation and biosynthesis of secondary metabolites in various fungi (Calvo et al. 2002).
The genetic mechanisms linking both processes are multifaceted and beginning to be unveiled
through molecular studies in several fungal species. The involvement of a G-
protein/cAMP/protein kinase A-mediated pathway in both asexual sporulation and mycotoxin
production in Aspergillus nidulans has provided significant insight into the close regulatory
interactions between these two phenotypes in other fungi. In addition, the mitogen-activated
protein (MAP) kinase and cyclin-dependent kinase pathways have also been shown to regulate
both conidiation and production of cercosporin in C. zeae-maydis (Shim and Dunkle 2003) and
fumonisins in F. verticillioides (Shim and Woloshuk 2001), respectively. Other cellular
regulators such as oxylipins and other lipid derivatives, polyamines, the CCAAT-binding protein
complex, and the proteins containing Trp-Asp (WD) repeats have also been shown to coordinate
regulation of both secondary metabolite production and sporulation in Aspergillus spp. (Calvo et
al. 2002; Tsitsigiannis and Keller 2006).
Coordinate regulation for conidiation and production of ESCs by E. fawcettii may mediate
similar regulatory pathways, as described in Aspergillus species. Such speculation in supported
by analysis of the EfPKS1 promoter region, which identified multiple binding sequences for
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transcriptional activators, including GATA factors of nitrogen and light regulation, PacC of pH
regulation, and the C/EBP-binding protein induced by cAMP. Furthermore, our results also
revealed that production of ESCs via a defined polyketide pathway is highly affected at the
transcriptional level by light, the levels of glucose and nitrogen sources, and pH values. In
addition to the binding motifs for global regulatory proteins, the EfPKS1 promoter contains two
distinct MRAGGGR motifs found in the promoter region of the gene encoding a conidiation-
specific Bristle (BrlA) transcriptional activator of A. nidulans (Adams et al. 1998). Furthermore,
the EfPKS1 promoter has two CATTCY motifs (Y is a pyrimidine) that serve as the binding sites
for the AbaA transcriptional activator (Andrianopoulos and Timberlake 1994). AbaA, regulated
via BrlA, has been shown to be required for the final stages of conidiphore development in A.
nidulans (Andrianopoulos and Timberlake 1994). The presence of conserved BrlA and AbaA
binding elements in the promoter of EfPKS1 strongly suggests that the EfPKS1 product might be
directly involved in conidial formation. Whether or not conidiation of E. fawcettii is regulated by
light, pH, carbon/nitrogen sources, or cAMP remains to be determined.
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Table 4-1. Conidial production in axenic cultures and pathogenicity assays on detached rough lemon leaves by inoculating with agar plugs cut from cultures of Elsinoë fawcettii wild type (WT), EfPKS1 null mutants (D1, D2, D3, and D4), and strains (C1 and C2) expressing a functional copy of EfPKS1.
Fungal strains or treatment
Conidial formation (conidia per mL)1
Lesion development2 Leaf spots showing lesions/total spots inoculated (%)
Wild type 3.4 ± 1.7 x 106 21/29 (72%) D1 5.0 ± 7.0 x 102 0/21 (0%) D2 4.1 ± 4.1 x 103 0/21 (0%) D3 1.1 ± 0.6 x 103 0/21 (0%) D4 6.2 ± 7.0 x 104 0/28 (0%) C1 3.9 ± 1.9 x 106 11/17 (65%) C2 2.4 ± 1.4 x 106 14/14 (100%) Agar plugs - 0/50 (0%)
1Conidia were produced in Fries medium in the dark and were determined with the aid of a hemacytometer by microscopy. Data are means and standard errors (± SEM) of ten different experiments with four replicates of each isolate. 2A 4-mm agar plug cut from mycelial mats was placed onto detached rough lemon leaves. Inoculated leaves were incubated in a moist chamber under florescent light for 25 days. The frequency of lesion formation is indicated as the number of inoculated spots developing scab lesions relative to the total number of spots inoculated.
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Figure 4-1. Putative polyketide synthase, EfPKS1, in Elsinoë fawcettii. A) the putative
polyketide synthase, EfPKS1 containing 2192 amino acids in Elsinoë fawcettii, showing a keto synthase (KS) domain with acyl binding cysteine, an acyltransferase (AT) domain containing pantotheine binding serine, a thioesterase/claisen cyclase motif (TE/CYC), and two acyl carrier protein (ACP) domains containing phosphopantotheine binding serine. Conserved amino acids for each of the domains are also indicated under the map, and the active amino acids are underlined. EfPKS1 lacks dehydratase (DH), enoyl reductase (ER), ketoacyl reductase (KR), and methyltransferase (ME) domains. B) and C) Phylogenetic relationships of EfPKS1, based on the conserved amino acids in the KS (B) or AT (C) domain, to other fungal PKSs (accession number) including: Bipolaris oryzae BoPKS (BAD22832); Cochliobolus heterostrophus ChPKS18 (AAR90272); Botryotinia fuckeliana BfPKS13 (AAR90249); Xylaria sp. XyPKS (AAM93545); Nodulisporium sp. NoPKS (AAD38786); Ophiostoma piceae OpPKS (ABD47522); Glarea lozoyensis GlPKS (AAN59953); Colletotrichum lagenarium ClPKS1(BAA18956); Sordaria macrospore SmPKS (CAM35471); Aspergillus clavatus AcPKSP (XP_001276035); Ceratocystis resinifera CrPKS1 (AAO60166); B. fuckeliana BfPKS12 (AAR90248); A. fumigatus AfPKSP (AAC39471); Chaetomium globosum CgPKS (XP_001219763); Emericella nidulans wA (1905375A); Nectria haematococca NhPKSN (AAS48892); Gibberella zeae GzPKS12 (AAU10633); A. nidulans AnSTCA (XP_681094); C. heterostrophus ChPKS19 (AAR90273); Cercospora nicotianae CnCTB1 (AAT69682); G. moniliformis GmPKS3 (AAR92210); G. moniliformis GmPKS4 (AAR92211); G. fujikuroi GfPKS4 (CAB92399); Mycosphaerella pini MpPKS (AAZ95017); A. flavus AfPKSA (AAS89999); A. oryzae AoPKS (BAE71314); A. parasiticus ApPKSL1 (Q12053); Leptosphaeria maculans LmPKS1 (AAS92537); C. heterostrophus ChPKS1 (AAB08104); G. moniliformis GmPKS11 (AAR92218); C. heterostrophus ChPKS25 (AAR90279); and Penicillium patulum Pm6MSAS (P22367). The phylogram was created with the program PHYLP (Saitou and Nei 1987).
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Figure 4-1. (Continued)
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Figure 4-2. Promoter analysis of 1.1 kb sequences upstream of the putative ATG translational start codon of EfPKS1 in both directions, identifying a number of putative binding sites for global transcriptional regulators such as AreA (nitrogen regulatory protein), the WC1/WC2 complexes (light regulatory proteins), PacC (ambient pH regulatory protein), and C/EBP (cAMP activated protein). The EfPKS1 promoter also has conserved sequences for recognition and binding of the conidial formation-associated BrlA and AbaA transcriptional activators in A. nidulans. Definition of mixed bases: R = A or G; M = A or C; Y = C or T.
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Figure 4-3. Differential expression of the EfPKS1 gene encoding a fungal polyketide synthase
and accumulation of ESC phytotoxins in a wild-type isolate Elsinoë fawcettii. Fungal isolate was grown on PDA (A and B), on complete medium containing different amounts of glucose (C), or on minimal medium containing different concentrations of ammonium nitrate (D) or with different pH values (E) under continuous light (LT) or darkness (DK). Unless indicated, fungal RNA was isolated from 7-day-old cultures, electrophoresed in an agarose gel containing formaldehyde, transferred onto a nylon membrane, and hybridized to an EfPKS1 gene-specific probe. Ribosomal RNA (rRNA) stained with ethidium bromide is shown for relative loading of the samples. ESCs were extracted with 5N KOH and measured at A480. The amounts of ESCs were determined by reference to a regression line was established using ethyl acetate-purified ESCs. ESC data represent the means of two different experiments with four replicates of each treatment. Vertical bars represent standard deviation. Means followed by the same letter are not different at judged by Duncan’s multiple range test at P < 0.0001.
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Figure 4-4. Strategy of EfPKS1 targeted disruption in Elsinoë fawcettii. A) Schematic depicting a split-marker strategy for EfPKS1 (indicated by shaded) targeted disruption in Elsinoë fawcettii. A 4.6-kb DNA fragment containing the 5’ end of EfPKS1 fused with the TrpC terminator of A. nidulans and truncated hygromycin phosphotransferase B gene (h/YG) and a 3.3-kb fragment containing the 3’ end of EfPKS1 joined with the TrpC promoter and truncated HY/g were amplified from the disruption construct pPKS0311 with the primers as indicated. The h/YG and HY/g fragment share 400 bp of overlapping sequence. The split marker fragments were directly transformed into protoplasts of the E. fawcettii wild-type strain for targeted gene disruption via double crossing-over recombination. The relative locations of DNA probes used for Southern and Northern-blot analyses are also indicated. Abbreviations for restriction endonuclease site: C, ClaI; X, XbaI. B) Southern-blot analysis of genomic DNA from wild type (WT) and four putative EfPKS1 disruptants (D1, D2, D3, and D4). Fungal DNA was cleaved with endonuclease ClaI, electrophoresed, blotted to a nylon membrane, and hybridized with the Probe 1. C) Southern-blot analysis of genomic DNA digested with XbaI and hybridized with the Probe 2. Sizes of hybridization bands are indicated in kilobase pairs (kb). Banding patterns confirm disruption of EfPKS1 gene.
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Figure 4-5. EfPKS1 gene expression and ESC production in EfPKS1 disruptants. A) Northern-
blot analysis of fungal RNA purified from wild type (WT) and three putative EfPKS1 disruptants (D1, D2, and D4) of Elsinoë fawcettii. RNA was denatured in a formaldehyde-containing gel, blotted to a nylon membrane, and hybridized to a DNA probe (Probe 3 in Fig. 4-4A). Gel stained with ethidium bromide indicates relative loading of RNA samples. Sizes of hybridization bands are indicated in kilobase pairs. B) Quantitative analysis of elsinochromes (ESCs) produced by wild type and EfPKS1 disruptants. Fungal isolates were grown on PDA under continuous light for 5 days. ESC pigments were extracted with 5N KOH from agar plugs covered with fungal hyphae and measured at A480. The concentrations of ESCs were calculated by referring to a regression line. Data represent the means of two different experiments with four replicates of each treatment. Vertical bars represent standard deviation. Means followed by the same letter are not different at judged by Duncan’s multiple range test at P < 0.0001. C) TLC analysis of ESCs extracted with acetone from the cultures of wild type, four EfPKS1 disruptants, and two strains (C1 and C2) expressing a functional EfPKS1 gene. ESCs were separated on a TLC plate coated with a 60 F254 fluorescent silica gel and developed with chloroform and ethyl acetate (1:1 by volume).
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Figure 4-6. Pathogenicity assays on detached rough lemon leaves inoculated with agar plugs (4-mm in diameter) of wild type, four EfPKS1 disruptants, and two strains (C1 and C2) expressing a functional EfPKS1 gene of Elsinoë fawcettii. Fungal isolates were grown on PDA for 7 days and agar plugs covered with mycelial mats were cut and placed onto detached rough lemon leaves (14 days after emergence) in which fungal mycelium directly contacts the leaf surface. Inoculated leaves (> 20 leaves) were incubated for lesion development in a moist chamber under constant fluorescent light. Photos were taken 25 days post inoculation. The inoculated areas were cropped and enlarged for better illustration of necrotic lesions. The mocks were treated with agar plugs without fungal mycelium.
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Figure 4-7. Pathogenicity assays using conidial suspensions of wild type, the EfPKS1 disruptant (D4), and the complementation strain (C2) of Elsinoë fawcettii on detached rough lemon leaves 3 days (A) or 7 days (B) after emergence. Fungal conidia (1 x 105 mL-1) were harvested and applied by applying 2 μL of suspension onto rough lemon leaves. Inoculated leaves (> 20 leaves) were incubated in a moist chamber. Formation of lesions was recorded 14 days post inoculation. The mocks were inoculated with water only. Reduction in lesion numbers and sizes by inoculation of EfPKS1 disruptant (D4) are indicated by arrows. Only some of the representative replicates of the inoculated leaves are shown.
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CHAPTER 5 CHARACTERIZATION OF A GENE CLUSTER REQUIRED FOR THE BIOSYNTHESIS OF
ELSINOCHROMES BY Elsinoë fawcettii
In this chapter, a mini-gene cluster required for elsinochrome (ESC) biosynthesis is
described. In the previous chapter, a polyketide synthase-encoding gene, EfPKS1 (Elsinoë
fawcettii polyketide synthase gene 1), was demonstrated to be required for ESC biosynthesis.
Chromosome walking and inverse PCR were utilized to extend the sequences adjacent to
EfPKS1 fragment and identify additional genes that might be involved in ESC production. In
addition to EfPKS1, nine putative open reading frames were identified in a span of 30 kb and
were designated as the ESC biosynthetic gene cluster. The ESC cluster includes genes encoding
a polyketide synthase (EfPKS1), a reductase (RDT1), an oxidoreductase (OXR1), a transcription
factor (TSF1), a membrane transporter (ECT1) and a prefoldin protein subunit (PRF1) that are
likely required for ESC biosynthesis, regulation, and translocation. Four other putative genes
(EfHP1, EfHP2, EfHP3, and EfHP4) apparently do not encode polypeptides with obvious
association with biosynthetic functions.
To determine if newly identified genes were required for ESC accumulation, the TSF1
gene was deleted. The TSF1 gene encodes the dual Cys2His2 zinc finger and Zn(II)2Cys6
binuclear cluster DNA-binding motifs and likely functions as a transcriptional regulator for ESC
production. The TSF1 deletion mutants of E. fawcettii failed to produce ESCs. Expression of the
RDT1, EfPKS1, PRF1, and EfHP1 but not the ECT1, OXR1, EfHP2, EfHP3, and EfHP4 genes
was markedly down-regulated in the TSF or EfPKS1 null mutants. The results indicate that the
RDT1, TSF1, PRF1, ECT1, EfPKS1, and EfHP1 genes are required for ESC biosynthesis and
accumulation.
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Introduction
Elsinoë fawcettii, the causal agent of scab disease of citrus, produces elsinochromes
(ESCs), causing cell death, necrotic lesions, and electrolytic leakage via production of reactive
oxygen species (Liao and Chung 2008a). An EfPKS1 (Elsinoë fawcettii polyketide synthase gene
1) was cloned and shown to be required for ESC production, and that ESCs are virulence factors
during citrus pathogenesis (Liao and Chung 2008b).
Biosynthesis of secondary metabolites in fungi has long been known to respond to
environmental cues, including the carbon/nitrogen source, light and pH, presumably mediated
through the global regulatory factors such as CreA responding to carbon suppression; AreA
responding to nitrogen signaling; PacC responding to ambient pH (Dowzer and Kelly 1989;
Kudla et al. 1990; Tilburn et al. 1995). The global regulatory networks have been proposed to be
regulated by a signaling pathway, involving the G protein/c-AMP/protein kinase-mediated
signaling (Calvo et al 2002; Yu and Keller 2005). In Chapter three, accumulation of ESCs in
culture was demonstrated to be affected by carbon and nitrogen sources, pH, and additional
environmental factors. Thus, it seems likely that production of ESCs is also regulated by similar
signaling pathways.
Genes for biosynthesis of secondary metabolites in filamentous fungi are often clustered
and coordinately regulated by a pathway-specific transcriptional regulator (Yu and Keller 2005).
A number of polyketide-derived fungal secondary metabolites, such as fumonisin, aflatoxin,
ochratoxin A, aurofusarin, and cercosporin, are synthesized by clustered genes within the
genomes of fungi (Proctor et al. 2003; Yu et al. 2004; Karolewiez and Geisen 2005; Malz et al.
2005; Chen et al. 2007). In this chapter, a mini gene cluster comprised of ten genes (RDT1, TSF1,
OXR1, EfPKS1, PRF1, ECT1 and EfHP1-4) is described in relation to ESC production in Elsinoë
fawcettii. To determine if the genes are coordinately regulated and are involved in ESC
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production, a TSF1 gene was cloned and characterized as embedded in the cluster and encoding
for a putative transcription activator containing dual Cys2His2 zinc finger and Zn(II)2Cys6
binuclear cluster DNA-binding domains.
Materials and Methods
Fungal Strains, Their Maintenance and Extraction/Analysis of ESC Toxin
The wild-type CAL WH-1 isolate of Elsinoë fawcettii Bitancourt & Jenkins (anamorph:
Sphaceloma fawcettii Jenkins) was previously characterized (Liao and Chung 2008b). All
procedures used for fungal culturing, toxin extraction, and screening for ESC-deficiency mutants
were previously described (Chapter 2, 3, and 4).
Chromosomal Walking and Sequence Analysis
Fungal DNA was isolated employing a DNeasy Plant Mini kit (Qiagen, Valencia, CA). A
genomic library of E. fawcettii was constructed from DNA digested with DraI, EcoRI, PvuI and
StuI, and ligated to adaptors using the Universal GenomeWalker kit (BD Biosciences, Palo Alto,
CA) according to the manufacture’s instructions. Primers were designed based the known
sequences and paired with adaptor primers to obtain DNA fragments harboring unknown
genomic regions using a Titanium or Advantage 2 DNA polymerase (BD Biosciences). In some
cases, DNA fragments were obtained by PCR with inverse primers from fungal DNA that was
digested with restriction endonucleases and self-ligated as previously described (Choquer et al.
2005). After purified with a DNA purification kit (Mo Bio Laboratories, Inc., Carlsbad, CA), the
amplified DNA fragments were either directly sequenced or first cloned into pGEM-T easy
vector (Promega) for sequence analysis at Eton Bioscience, Inc. (San Diego, CA).
Oligonucleotides used for PCR and sequencing were synthesized by Integrated DNA
Technologies (Coralville, IA) and Allele Biotechnology and Pharmaceuticals, Inc., (San Diego,
CA). Similarity searches using a BlastX program (Altschul et al., 1997) were performed at the
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National Center for Biotechnology Information (http://www.ncbi.nlm.nih.gov/). Prediction of
open reading frames (ORFs) and exon/intron junctions were first performed using the gene-
finding software at http://www.softberry.com and were further confirmed by comparing genomic
and cDNA sequence. Functional domains were identified using the PROSITE database in the
ExPASy Molecular Biology Server (http://us.expasy.org) (Gasteiger et al. 2003) and
Motif/ProDom and Block programs (Henikoff et al. 2000) at http://motif.genome.jp/. Analysis of
the promoter regions was conducted using regulatory sequence analysis tools (van Helden, 2003)
at http://rsat.ulb.ac.be/rsat/. Palindrome searches were performed at
http://bioweb.pasteur.fr/seqanal/interfaces/palindrome.html.
Targeted Gene Disruption and Genetic Complementation
To disrupt the TSF1gene in E. fawcettii, a 5.34-kb DNA fragment encompassing the whole
TSF1 ORF and flanking sequences was amplified by PCR with primers efup 11 (5’-
CATCTCGCATATCTGGACCCGTC-3’) and efup28 (5’-CGGGCTATTCTTAGAGCAGAG-
3’). The amplified DNA fragment was purified with a DNA purification kit and cloned into
pGEM-T easy vector to become pSTSF1128. Plasmid pSTSF1128 was digested with NruI,
blunted, and to accommodate an end-filled 2.1-kb fragment harboring the hygromycin
phosphotransferase B gene (HYG) cassette under the control of the Aspergillus nidulans trpC
gene promoter and terminator from pUCATPH (Lu et al. 1994) to create the disruption construct,
pTSF1128 (Fig. 5-3). A split marker strategy was applied to facilitate double crossing-over
recombination as previously described (Choquer et al. 2005). Briefly, a 4.4-kb DNA fragment
containing truncated 5’ TSF1 fused with 5’ HYG and a 4.2-kb fragment encompassing 3’ TSF1
linked to 3’ HYG were amplified, respectively, with primers efup11/hyg3 (5’-
GGATGCCTCCGCTCGAAGTA-3’) and efup28/hyg4 (5’-CGTTGCAAGAACTGCCTGAA-3’)
from pTSF1128 using the Takara Ex Tar PCR system (Takara Bio USA, Madison, WI). Fungal
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protoplasts were released from fungal hyphae by a mixture of cell-wall degrading enzymes as
previously described (Chung et al. 2002). Fungal transformation using a CaCl2 and polyethylene
glycol-mediated method was performed by mixing PCR fragments with protoplasts (1 x 105) as
previously described (Chung et al. 2002). The two hybrid fragments share 800 bp of overlapping
sequence within the HYG gene. The HYG gene cassette is not functional until recombination
takes place between the two truncated HYG DNA fragments. Fungal transformants were
recovered from RMM medium containing 200 µg mL-1 hygromycin (Roche Applied Science,
Indianapolis, IN) after 2 to 3 weeks and were screened for the loss of ESC production
(red/orange pigments) on thin PDA.
For genetic complementation, a functional TSF1 gene and its 5’ non-translated region was
amplified from genomic DNA with primers efup11 and efup28 by an Expand High Fidelity PCR
system (Roche Applied Science) and confirmed by sequencing. The amplified TSF1 gene
cassette was co-transformed with plasmid pBARKS1 plasmid harboring a phosphinothrin
acetyltransferase gene under control of the A. nidulans trpC promoter that is responsible for
bialaphos resistance (Pall and Brunelli, 1993). Transformants were first identified from a
medium supplemented with 50 µg/mL bialaphos (Gold Biotech, St. Louis, MO) and tested for
production of the red/orange pigments (ESCs) on thin PDA plate as previously described (Liao
and Chung 2008a; 2008b).
Molecular Techniques
Unless otherwise specified, standard molecular techniques were used for endonuclease
digestion of DNA, electrophoresis, and Southern- and Northern-blot hybridizations. Plasmid
DNA was propagated in Escherichia coli DH5α bacterial cells and purified using a Wizard DNA
purification kit (Promega). Fungal RNA was purified by Trizol reagent per manufacture’s
directions (Invitrogen, Carlsbad, CA). Single and double strand cDNA was prepared with a
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cDNA synthesis kit (BD Biosciences) and amplified by reverse transcriptase (RT)-PCR with
gene-specific primers. The resulting fragments were purified and directly subjected to sequence
analysis. DNA probes used for Southern- and Northern-blot hybridization were labeled by PCR
to randomly incorporate digoxigenin (DIG)-11-dUTP (Roche Applied Science) into DNA with
gene-specific primers. Procedures used for probe labeling, hybridization, post-hybridization
washing and immunological detection of the probe using a CSPD (C18H19Cl2O7PNa2)
chemofluorescent substrate for alkaline phosphatase were performed following the
manufacturer’s recommendations (Roche Applied Science).
Conidia Production and Pathogenicity Assays
Conidia were prepared as described in the Chapter 4. Fungal pathogenicity was evaluated
on detached rough lemon (Citrus jambhiri Lush) leaves inoculated with agar plugs as previously
described (Liao and Chung, 2008b). The inoculated leaves were incubated in a moist chamber
under constant fluorescence light at an intensity of 3.5 joules m-2 s-1 and lesion formation was
monitored weekly. Rough lemon trees were maintained in greenhouse and leaves of 7-10 days
after flushing, with size approximately length 2.2-3.2 cm and width 1-1.5 cm, were harvested for
pathogenicity assays.
Nucleotide Sequences
Sequence data reported in this article can be retrieved from the EMBL/GenBank Data
Libraries under Accession nos. EfHP1 (EU414199), EfHP2 (EU414200), EfHP3 (EU414201),
RDT1 (EU401704), TSF1 (EU401705), OXR1 (EU401706), EfPKS1 (EU086466), PRF1
(EU401707), ECT1 (EU414198), and EfHP4 (EU414202).
105
Results
Sequence Analysis and Determination of Open Reading Frames (ORFs)
A polyketide synthase gene (EfPKS1) required for elsinochromes (ESCs) biosynthesis has
been determined as described in Chapter 4. The EfPKS1 gene disrupted mutants, D1, D2, D3,
and D4, were completely blocked in ESC production. Sequence analysis beyond the EfPKS1
gene was performed to determine if any of the genes adjacent to EfPKS1 are also required for
ESC biosynthesis. Using a combination of chromosome walking and inverse PCR cloning
strategies, over 30-kb of adjacent sequences were obtained after multiple rounds of polymerase
chain reaction (PCR). In each round, new primers complementary to the end of assembled
sequences were designed, synthesized and used to amplify overlapping DNA fragments from the
genome of E. fawcettii. The presence of exons/introns and the identification of putative ORFs
were first performed using computer software and were further confirmed by comparison of
genomic and cDNA sequences. Analysis of the compiled sequences led to identify nine putative
ORFs, in addition to the EfPKS1 gene (Table 5-1; Fig. 5-1).
A similarity search in the NCBI database using BLASTX was performed to predict the
function of the translated polypeptide. A PRF1 gene, located downstream from EfPKS1, contains
a 111-bp intron and encodes a putative polypeptide similar to prefoldin subunit 3. The putative
ECT1 gene product, excluding a 45-bp intron, displays strong similarity to numerous
hypothetical proteins and membrane transporters, with the highest hit to nitrate transporter of
Aspergillus terreus (E value = 3e-69; Table 5-1). A TSF1 gene that is located upstream and
transcribed divergently from EfPKS1 encodes a putative protein, showing strong similarity to
many zinc finger transcriptional factors of fungi. A RDT1 gene, located further upstream from
TSF1, has a 47-bp intron and encodes a putative polypeptide similar to a wide range of
reductases, with strong similarity to 1,3,8-trihydroxy naphthalene (T3HN) reductase involved in
106
melanin biosynthesis (Table 5-1). An OXR1 gene contains a 45-bp intron and is located between
the EfPKS1 and TSF1 genes. The OXR1 protein, rich in proline, has low similarity to
malate:quinone oxidoreductases of bacteria (Table 5-1). Three putative ORFs (designated as
EfHP1-3) upstream of the RDT1 gene encode hypothetical proteins with unknown functions. A
small segment, consisting of 44 amino acids, in the translated product of EfHP2, however,
displays low similarity to putative cation/multidrug efflux pump of Marinomonas sp. (Table 5-
1). The EfHP1 and EfHP3 genes have introns of 57 and 69 bp, respectively, whereas EfHP2 is an
intronless gene. A small EfHP4 ORF, interrupted by 54-bp introns, is located downstream of
ECT1 and encodes a putative polypeptide, showing low similarity to isoleucyl t-RNA synthase
which did not appear to involve in metabolic functions. Sequencing beyond the EfHP1 or EfHP4
gene failed to produce reliable sequences after several attempts with different primers (data not
shown).
Expression of Putative ORFs and ESC Accumulation
In order to determine if the genes identified within the cluster were expressed and
coordinately regulated under the conditions favorable for ESC accumulation, Northern-blot
hybridization of RNA from E. fawcettii was conducted to examine the expression profiles of the
RDT1, TSF1,OXR1, EfPKS1, PRF1, ECT1 genes and four EfHP genes (Fig. 5-2A). All genes
except for EfHP3 were favorably expressed when the fungus was under nitrogen starvation and
their transcripts were nearly undetectable in the presence of ammonium nitrate. Expression of the
EfHP3 gene appeared to be constitutive as its transcript remained unchanged in all conditions
tested. Noticeably, accumulation of the TSF1, EfPKS1, PRF1, ECT1, and EfHP2 gene transcripts
increased considerably when the fungus was incubated in alkaline conditions. Under acidic
conditions (pH 4), the RDT1 and EfHP1 gene transcripts accumulated slightly but not
significantly higher compared to those in alkaline conditions. By contrast, expression of the
107
EfHP3 or OXR1 gene was not affected by pH, as their transcripts were detected at similar levels
both in acidic and alkaline conditions. Apparently, the EfPKS1, PRF1 and ECT1genes were
preferably expressed in the conditions with higher amounts of glucose, whereas accumulation of
the TSF1 and RDT1 gene transcripts were repressed. Expression of the EfHP3 gene was not
regulated by glucose as its transcript accumulated equally well in both conditions (Fig. 5-2A).
Quantification assays for the accumulation of elsinochromes (ESCs) revealed that large quantity
of ESCs was exclusively detected when the fungus was cultured in the absence of nitrogen, in
alkaline conditions (pH 8.0), or in the presence of higher amounts of glucose (Fig. 5-2B).
Addition of ammonium nitrate, reducing the glucose concentration to 2 g L-1, or changing the
medium pH to acidic conditions (pH 4.0) completely suppressed ESC production.
Promoter Analysis for Identifying DNA Binding Motifs
The promoters of ten putative genes were analyzed to identify potential binding sequences
for common regulatory elements such as the nitrogen regulatory protein (AreA), the carbon
regulatory protein (CREA), the pH regulatory protein (PacC), and the light responsive proteins
(WC1/WC2 complex). Analysis sequences upstream of the putative ATG translational start
codon identified several consensus sequences in the RDT1, TSF1, OXR1, EfPKS1, PRF1, ECT1,
and EfHP1-4 promoters (Table 5-2). The consensus TATA motif was found in the promoters of
all genes but TSF1, OXR1, PRF1, and EfHP3. All genes, but EfHP4 contain at least one CAAT
or CCAAT consensus sequence in their promoter regions. The pH regulatory PacC-binding
sequence (5’-GCCA(A/G)G-3’) was identified only in the promoter regions of TSF1, OXR1,
EfPKS1, PRF1, ECT1and EfHP2-4. All genes, except for EfHP3, have one or multiple GATA
consensus sequence that is potentially recognized and bound by the nitrogen regulatory AreA
protein or the light regulatory transcriptional WC1/WC2 complex (Kudla et al. 1990; Marzluf
1997; Linden et al. 1997). However, none of the promoter regions has the binding sequence (5’-
108
(G/C)PyGGGG-3’) that is recognized by the CreA carbon repressor. The promoter regions of the
RDT1, EfPKS1, and ECT1 genes have a consensus sequence, 5’-(A/C)(A/G)AGGG(A/G)-3’ that
serves as a binding site for the conidial formation-related BrlA transcriptional activator in A.
nidulans (Adams et al, 1998). The promoter regions of the RDT1, OXR1, EfPKS1, and ECT1
genes, however, have a consensus sequence, 5’-CATTC(C/T)-3’ that acts a binding site for the
AbaA transcriptional activator involved in conidiophore development in A. nidulans
(Andrianopoulos and Timberlake 1994). Two palindrome sequences, 5’-TCG(N2-4)CGA-3’ and
5’-CGG(N3-11)CCG-3’, were also identified in the promoter regions of some but not all genes
(Table 5-2).
Targeted Disruption of the TSF1 Gene and Genetic Complementation
To determine if the genes that are clustered with TSF1 are also involved in ESC
biosynthesis and regulation, I characterized the TSF1 gene encoding a putative transcriptional
activator. The TSF1 gene contains 3075 nucleotides, interrupted by four introns of 49, 50, 43,
and 53 bp in lengths. The translated 959 amino acids of the TSF1 gene displays strong similarity
to numerous conserved proteins from the sequenced genomes of fungi and contains dual
Cys2His2 type zinc finger (CTYCGHSFTRDEHLERHILTH and
CFTCHMSFARRDLLQGHYTVH) and GAL4-like Zn2Cys6 binuclear cluster DNA-binding
(CSNCAKTKTKCDKKFPCSRCASRNLRC) domain signatures. The regulatory function of the
TSF1 gene product in relation to the biosynthesis of ESCs was determined genetically, by
creating and analyzing targeted disruptants that were specifically mutated at the TSF1 locus. To
increase the efficiency of recovery of transformants with targeted gene disruption, two split DNA
fragments overlapping 800 bp within the HYG cassette were amplified separately from the
disruption construct pTSF1128 (Fig. 5-3A) and directly transformed into wild-type of E.
fawcettii. Since the HYG cassette was truncated in either fragment, only transformants with the
109
restored HYG function via homologous recombination would survive and form colonies on the
regeneration medium supplemented with hygromycin. All transformants recovered were then
screened for production of red/orange pigments (ESCs) on a thin PDA under constant fluorescent
light. Of 20 transformants tested, three failed to accumulate the red/orange pigments and were
considered TSF1 disruptants. Successful disruption of the TSF1 gene was confirmed by Southern
blot analysis. Hybridization of genomic DNA digested with PvuII endonuclease and hybridized
to a TSF1 gene probe resulted in a 4.8-kb hybridizing band in the wild type and two hybridizing
bands with expected sizes of 3.9 and 3.2 kb, as a result of integration of the HYG cassette, in the
putative disruptants (Fig. 5-3B). Hybridization of genomic DNA cleaved with BglI and PvuII
also yielded different banding patterns between the wild type and the putative disruptants as
expected (Fig. 5-3C), indicating a specific disruption at the TSF1 locus.
Northern-blot analysis was conducted to determine if the putative mutants accumulated the
TSF1 transcript. As shown in Fig. 5-4A, hybridization of total RNA identified a sole TSF1
transcript of 3.1-kb in size from wild type, but not from three disruptants. Apparently, integration
of the HYG cassette within the TSF1 ORF has completely abolished expression of the TSF1
gene, indicating they were TSF1 null mutants. Functional complementation was performed to
further determine the role of TSF1 in relation to the biosynthesis of ESCs. Transformants were
screened for recovery of the red-pigmented fungal strains that acquired and expressed a
functional TSF1 gene cassette. Two fungal strains (CA and CB) accumulated low amounts of the
red/orange pigments were selected for further characterization. Northern-blot analysis revealed
that the TSF1 transcript was detected in both CA and CB strains, but not in their progenitor T3
strain (Fig. 5-4A). Phenotypic analyses indicated that the TSF1 disruptants failed to accumulate
ESCs in axenic cultures compared to wild type, as either assayed spectrophotometry after KOH
110
extraction (Fig. 5-4B) or by TLC analysis (Fig. 5-4C). Compared to wild type, the CA and CB
complementation strains produced much less ESCs on PDA (Fig. 5-4B). TLC analysis of the
pigments extracted from the CA strain indicated that the band with Rf 0.68 was the most
abundant pigment (band 1), whereas the extracts from wild type showed three derivatives of
pigments (Rf 0.68, Rf 0.50, and Rf 0.22) with band 3 as the major compound (Fig. 5-4C).
Spectrophotometric scanning indicated that the acetone extracted pigments from wild type, CA,
and CB strains, displayed a strong absorbance at 460 nm with two minor peaks at 530 and 570
nm, whereas all ∆tsf1-disrupted mutants (T1, T2, and T3) had no absorbance peaks.
Gene Regulation by TSF1 and Feedback Inhibition
The central role of the TSF1 gene product as a transcriptional activator was assessed for
expression of the clustered genes in two TSF1 disruptants (Fig. 5-5). As shown in Fig. 5-5,
disruption of the TSF1 gene caused a decreased accumulation of the RDT1, EfPKS1, PRF1, and
EfHP1 gene transcripts, but did not cause a drastic reduction for expression of the OXR1, ECT1,
EfHP2, and EfHP3 genes. Expression of the EfPKS1 gene was restored in the CA and CB
complementation strains. Accumulation of the gene transcripts was also examined in an EfPKS1
null mutant (D4) that is defective in ESC production. Northern hybridization analysis revealed a
marked reduction of transcripts of the RDT1, TSF1, PRF1, ECT1, and EfHP1 genes in the D4
mutant (Fig. 5-6). Accumulation of the RDT1, TSF1, PRF1, ECT1, and EfHP1 gene transcripts
was nearly restored in strains (C1 and C2) expressing a functional copy of the EfPKS1 gene. In
contrast, expression of the OXR1, EfHP2, and EfHP3 gene transcripts was apparently not
influenced by disruption of the EfPKS1 gene, as evidenced by the fact that their transcripts
accumulated to the levels comparable to those of wild type (Fig. 5-6).
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Discussion
Elsinochrome (ESC) phytotoxins produced by many Elsinoë species contain a
perylenequinone backbone and is likely synthesized via a defined polyketide pathway. I have
previously demonstrated that deletion of the EfPKS1 gene encoding a fungal polyketide synthase
in an isolate of E. fawcettii leads to complete inability in the production of ESC which
demonstrates that ESC plays an essential role in fungal virulence (Liao and Chung 2008b). The
genes involved in the biosynthesis of fungal polyketide compounds are often closely linked in
the genome. The case for the biosynthesis of ESCs by E. fawcettii, is no exception. In this
chapter, the regions flanking EfPKS1 were sequenced to obtain a 30-kb continuous DNA stretch.
Nine additional putative ORFs were identified, some of which encode polypeptides likely
involved in biosynthesis, regulation, and accumulation of ESCs.
EfPKS1 functions in the assembly of the polyketide backbone of ESCs in an analogous
fashion to fatty acid and polyketide biosynthesis (Fig. 5-7). The putative biosynthetic pathway
begins with the condensation of acetyl-CoA (starter) and malonyl-CoA (extender) units. EfPKS1
contains several conserved domains including a keto synthase (KS), an acyltransferase (AT), a
thioesterase (TE) and two acyl carrier protein (ACP) domains that may act cooperatively to form
the polyketomethylene backbone of ESCs. The malonyl-CoA subunit is assumed to attach to the
ACP domains of EfPKS1 to form a phosphopantotheine (PPT) complex (Watanabe and Ebizuka
2004) that accepts a unit from acetyl-CoA via the function of the AT domain. The KS domain of
EfPKS1 catalyzes condensation of the malonyl- and acetyl-CoAs by decarboxylation. After each
cycle of condensation, the malonyl keto group is reduced. The putative polyketide synthase
encoded by EfPKS1 iteratively catalyses the synthesis by incorporating two carbons in each
cycle into a linear polyketide chain which is then released and cyclized through a TE domain in
the EfPKS1 (Birch 1967). Additional modification steps are present to produce a heptaketide
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backbone of ESCs. ESCs have a bilateral symmetrical structure (Fig. 5-7). Thus, formation of the
mature ESCs is likely mediated by dimerization.
In addition to the EfPKS1 gene, the RDT1 gene encoding a putative reductase, the TSF1
gene encoding a putative transcriptional activator, and the OXR1 gene encoding a putative
oxidoreductase are likely involved in modification of ESC backbone (Fig. 5-7). The ECT1 gene
encoding a probable membrane transporter is likely functioning in toxin secretion outside the
fungal cells to avoid toxicity (Fig. 5-7). In addition, there is no methyltransferase-coding gene in
the ESC cluster even though ESC has four methyl groups at position C3, C7, C8, and C12
(Weiss et al. 1965; Lousberg et al. 1969). It appears that the identified ESC gene cluster does not
contain all the genes responsible for ESC biosynthesis. The role of the PRF1 gene encoding a
putative prefoldin protein in relation to ESC production remains unknown. Similarly, the
remaining four ORFs (EfHP1-4) encode hypothetical proteins with unknown functions. Whether
or not they are involved in the ESC production will require further investigation by a deletion
strategy for the corresponding genes.
All the putative ORFs identified in the cluster were expressed as judged by Northern-blot
analysis. Apparently, ESCs were favorably produced when the fungus was cultured in lower
nitrogen, higher pH, and higher carbon supply. However, accumulation of the gene transcripts
was not fully congruent with the conditions conductive for ESC production. Expression of all
ORFs other than EfHP3 and accumulation ESCs were regulated under nitrogen starvation, but
obviously lacked strong correlation between gene expression and ESC accumulation in response
to pH or carbon source. Analysis of the promoter regions of the ESC clustering genes for
possible DNA binding sites of global transcriptional regulators revealed that all ten genes contain
nitrogen or light regulatory binding elements (GATA) in their promoter regions that are
113
recognized by AreA nitrogen regulator (Marzluf 1997; Wilson and Arst 1998), and the
WC1/WC2 light-responsive regulator (Linden et al. 1997). The GCCARG consensus motif
involved in the binding of the pH-responsive PacC regulator (Espeso et al. 1997) was found in
the 5’-untranslated regions of the TSF1, EfPKS1, PRF1, ECT1 and OXR1 genes but not RDT1
promoter regions. Expression of TSF1, EfPKS1, PRF1, and ECT1 but not RDT1 and OXR1 genes
increased at alkaline pH. Interestingly, PacC has been reported to regulate fungal virulence genes
required for phytopathogens (Rollins and Dickman 2001; Caracuel et al. 2003; You et al. 2007).
Thus, I predict that PacC may also function as a fungal virulence factor in E. fawcettii, likely via
regulation of the genes involved in ESC biosynthesis.
Many of the Zn2Cys6 harboring transcriptional activators have been shown to recognize
and bind the palindrome DNA sequence with inverted repeats of CGG or TCG elements
separated by a spacer with various nucleotides, such as [5’-CGG(N3-N11)CCG-3’] or [5’-
TCG(N2-N4)CGA-3] (Marmorstein and Harrison 1994; Li and Kolattukudy 1997; Fernandes et
al. 1998; Ehrlich et al. 2002). Promoter analysis also identified similar palindrome DNA
sequence in the 5’- untranslated regions of TSF1, OXR1, EfPKS1, and PRF1, that may also be
involved in transcriptional regulation. Northern-blot analysis also uncovered that not all of the
clustered genes were coordinately regulated through the putative transcriptional regulator, TSF1,
implying the requirement of other transcriptional regulators whose coding sequences are not
linked to the ESC gene cluster. However, deletion of the TSF1 gene resulted in fungal mutants
that completely fail to accumulate any detectable TSF1 transcript and ESCs, indicating the TSF1,
likely acts as a core transcriptional activator, playing an essential role in ESC biosynthesis.
Deletion of the TSF1 gene influenced expression of the RDT1, EfPKS1, and PRF1 gene
considerably, yet had little effect for transcriptional suppression of the ECT1 and OXR1 genes.
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Similarly, it is not yet clear whether or not the putative EfHP1-4 ORFs close to the ESC cluster
are also involved in ESC biosynthesis even though the expression of some of these genes was
regulated by nitrogen starvation and affected by the deletion of EfPKS1 or TSF1 gene. Thus, the
function of the ESC genes other than EfPKS1 and TSF1 in the biochemical pathway leading to
ESC production can not be conclusively determined until each of the genes is inactivated.
Expression of the ESC clustering genes in an EfPKS1 null mutant reveals a transcriptional
feedback inhibition, in which deletion of the EfPKS1 gene suppressed expression of the RDT1,
TSF1, PRF1, and ECT1 genes in the cluster. Expression of a copy of the functional EfPKS1 gene
in a respective null mutant restored their expression to the extent comparable to those of their
wild-type progenitor, further supporting the requirement of the RDT1, TSF1, PRF1, and ECT1
genes for ESC biosynthesis.
In a prior study, deletion of the EfPKS1 gene gave rise to a remarkable reduction in
conidiation in addition to deficiency in the ESC production. Similar to the EfPKS1-disrupted
mutants, the TSF1 null mutants were also severely disrupted in conidial production (data not
shown). The connections between production of secondary metabolites and cell development
and/or differentiation have also been investigated in other filamentous fungi (Adams and Yu
1998; Calvo et al. 2002; Yu and Keller 2005; Brodhagen and Keller 2006). Interestingly,
examination of the 5’-untranslated regions revealed the presence of the consensus MRAGGGR
motifs in the promoter regions of the RDT1, EfPKS1, and ECT1 genes, which are presumably
involved in the binding for a conidiation-specific Bristle (BrlA)-like transcriptional activator as
described in A. nidulans (Adams et al. 1998). In addition, the consensus CATTCY motifs,
recognized by the AbaA transcriptional activator (Andrianopoulos and Timberlake 1994), are
found in the RDT1, OXR1, EfPKS1, and ECT1 gene promoters. AbaA is activated by BrlA and is
115
involved in conidiphore development of A. nidulans (Andrianopoulos and Timberlake 1994). It
is possible that the proteins or intermediates involved in the ESC biosynthesis and conidial
formation might be coordinately regulated, at lease in part, by common transcriptional regulators
in a complex and intertwined networks that include the G-protein/cAMP/protein kinase A- and
the mitogen-activated protein (MAP) kinase-mediated signaling cassettes as described in other
filamentous fungi (Calvo et al. 2002).
Expression a functional TSF1 gene cassette in the respective null mutants failed to fully
restore conidiation, ESC production, or fungal pathogenesis. It is very unlikely that failure to
completely restore the mutant phenotypes was attributed to the transformed TSF1 gene.
Sequence analysis of the transformed TSF1 gene cassette revealed no nucleotide substitutions or
insertions (data not shown). Northern-blot analysis also showed a normal expression of the TSF1
gene in the recombinant transformants comparable to those of wild type. The failure of TSF1 to
complement ESC production, conidiation, and virulence, when controlled by its endogenous
promoter, was somewhat surprising and highlighted the requirement of specific regulation for the
function of TSF1 in particular and all other genes in the cluster in general.
As summarized in Fig. 5-8, I propose a regulatory model for the possible linkage of ESC
biosynthesis and environmental cues. Elsinoë fawcettii responds to various external signals, such
as light, pH, and nutrients. Subsequently, membrane receptors relay the external stimuli into
fungal cells to elicit the global signaling pathways, such as G protein-mediated signaling
pathways to release various secondary messengers. These second messengers, such as cAMP,
Ca2+, 1,4,5-trisphosphate (IP3), or others, in turn trigger global transcription factors that directly
or indirectly activate TSF1. Since the EfPKS1- and TSF1- disrupted mutants resulted in a
116
reduced conidiation, it is very likely that biosynthesis of ESC and fungal conidiation are
coordinately regulated.
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Table 5-1. Elsinochrome (ESC) biosynthetic gene cluster and adjacent EfHP1-4 genes encoding hypothetical proteins in Elsinoë fawcettii
Gene (accession number)
Length (bp)
Intron no. (size in bp)
Amino acids
Closest blast match proteins and species (accession no.)
Amino acid similarity (%)
E-value
Hypothetical protein, Botryotinia fuckeliana (EDN21223)
224/264 (84%)
6e-110
RDT1 (EU401704)
851 1 (47) 267
1,3,8-trihydroxynaphthalene reductase, Alternaria alternata (BAA36503)
221/261 (84%)
1e-108
Hypothetical protein, Phaeosphaeria nodorum (EAT80399)
558/956 (58%)
0 TSF1 (EU401705)
3075 4 (49, 50, 43, and 53)
959
Transcription factor Cmr1, Cochliobolus heterostrophus (ABI81496)
659/1032 (63%)
0
OXR1 (EU401706)
744 1 (45) 232 Malate:quinone oxidoreductase, Pseudomonas syringae (AAY36032)
65/163 (39%)
1.1
EfPKS1 (EU086466)
6631 1 (52) 2192 Fungal type I polyketide synthase, Bipolaris oryzae (BAD22832)
1656/2197 (75%)
0
Hypothetical protein, Phaeosphaeria nodorum (EAT80391)
147/178 (82 %)
1e-67
PRF1 (EU401707)
705 1 (111) 197
Probable prefoldin subunit 3, Neosartorya fischeri (EAW23892)
151/190 (79 %)
2e-57
Hypothetical protein, Phaeosphaeria nodorum (EDN17791)
273/522 (52 %)
2e-82
ECT1 (EU414198)
1563 1 (45) 505
Highly affinity nitrate transporter, Aspergillus terreus (EAU39122)
260/513 (50 %)
3e-69
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Table 5-1. (Continued) Gene (accession number)
Length (bp)
Intron no. (size in bp)
Amino acids
Closest blast match proteins and species (accession no.)
Amino acid similarity (%)
E-value
EfHP1 (EU414199)
993 1 (57) 311 Hypothetical protein, Chaetomium globosum (EAQ88529)
71/147 (48%)
8e-06
EfHP2 (EU414200)
1158 0 385 Putative cation/multidrug efflux pump, Marinomonas sp. (EAQ67386)
44/94 (46%)
1.0
EfHP3 (EU414201)
819 1 (69) 249 Hypothetical protein, Coprinopsis cinerea (EAU83036)
60/117 (51%)
3e-06
EfHP4 (EU414202)
423 1 (54) 122 Isoleucyl-tRNA synthase, Bacillus subtilis (CAB13417)
39/80 (48%)
0.26
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Table 5-2. Promoter analysis of genes in the elsinochrome (ESC) biosynthetic gene cluster of Elsinoë fawcettii
Gene RDT1
TSF1 OXR1 EfPKS1
PRF1
ECT1
EfHP1
EfHP2
EfHP3
EfHP4
TATA 1 0 0 1 0 1 1 1 0 1 CCAAT or CAAT 7 7 7 9 8 2 7 3 4 0 AreA or WC1/WC2 GATA
3 4 1 8 5 1 1 6 0 7
pH regulatory GCCA (A/G)G
0 1 1 4 1 1 0 1 1 1
BrlA (A/C)(A/G)AGGG(A/G)
1 0 0 3 0 1 0 0 0 0
AbaA CATTC (C/T)
3 0 3 2 0 2 0 0 0 0
TCG(N2-
4)CGA 0 1,
(N3) 1, (N3)
2, (N2 & 3)
2, (N3 &
4)
0 0 0 0 0 Palin-drome
CGG(N3-
11)CCG 0 2, (N5 &
11) 2, (N8 &
9) 1, (N10 )
1, (N3 )
0 0 0 0 0
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Figure 5-1. Elsinochrome (ESC) biosynthetic gene cluster. The 30-kb DNA region harboring 10
genes is shown. The putative genes include RDT1 (reductase 1), TSF1 (transcription factor 1), OXR1 (oxidoreductase 1), EfPKS1 (polyketide synthase 1), PRF1 (prefoldin 1), ECT1 (transporter 1). The nucleotide sequence of the 5’ end flanking region contains three ORFs designated EfHP1, EfHP2, and EfHP3, and the 3’ end contains one ORF designated EfHP4.
121
Figure 5-2. Northern-blot analysis of gene expression and elsinochrome (ESC) production in
response to nitrogen, pH, and glucose in Elsinoë fawcettii. Fungal isolate was grown on complete medium containing different amounts of glucose, or on minimal medium containing different concentrations of ammonium nitrate or buffered to various pH as indicated under continuous light. A) Fungal RNA was isolated from 7-day-old cultures, electrophoresed in an agarose gel containing formaldehyde, transferred onto a nylon membrane, and hybridized to the gene-specific probes. Ribosomal RNA (rRNA) stained with ethidium bromide is shown for relative loading of the samples. B) ESCs were extracted with 5 N KOH and measured at A480. The amounts of ESCs were determined by reference to a regression line that was established using ethyl acetate-purified ESCs. ESC data represent the means of two different experiments with four replicates of each treatment. Vertical bars represent standard deviation. Means followed by the same letter are not different at judged by Duncan’s multiple range test at P < 0.0001.
122
Figure 5-3. Targeted gene disruption of TSF1 encoding a putative transcription regulator which contains dual Cys2His2 type zinc finger and GAL4-like Zn2Cys6 binuclear cluster DNA-binding domain using a split-marker strategy in Elsinoë fawcettii. A) Restriction maps of the TSF1 gene in the genome of wild type (WT) and ∆tsf1-disrupted mutant. Two truncated TSF1 fragments fused with an overlapping HY/YG (hygromycin resistance gene cassette) were amplified by PCR with Oligonucleotide primers (up11 paired with hyg3; up28 paired with hyg4) as indicated. Note: drawing is not to scale. B, BglI; N, NruI; P, PvuII. B) and C) Southern-blot analysis of genomic DNA from wild type (WT) and three ∆tsf1-disrupted mutants (T1, T2 and T3). Fungal DNA was digested with PvuII (B) or BglI/PvuII (C), electrophoresed, blotted onto a nylon membrane and hybridized with TSF1 gene specific probe amplified by primers, up 26/up28, as indicated in A. Hybridizing patterns indicate disruption of the TSF1 gene.
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Figure 5-4. TSF1 gene expression and ESC production in TSF1 disruptants. A) Northern-blot analysis of fungal RNA purified from wild type (WT), three putative ∆tsf1-disrupted mutants (T1, T2 and T3), and two TSF1-complemented strains (CA and CB) of Elsinoë fawcettii. RNA was denatured in a formaldehyde-containing gel, blotted to a nylon membrane, and hybridized to a DNA probe (probe amplified by primers, up26/up28 in Fig. 5-3A). Gel stained with ethidium bromide indicates relative loading of the RNA samples. Sizes of hybridization bands are indicated in kilobase pairs. B) Quantitative analysis of ESCs produced by wild type, TSF1 disruptants and complemented strains. Fungal isolates were grown on PDA under continuous light for 7 days. ESC pigments were extracted with 5N KOH from agar plugs covered with fungal hyphae and measured at A480. The concentrations of ESCs were calculated by referring to a regression line. Data represent the means of two different experiments with four replicates of each treatment. Vertical bars represent standard deviation. Means followed by the same letter are not different at judged by Duncan’s multiple range test at P < 0.0001. C) TLC analysis of ESCs produced by wild type, three ∆tsf1-disrupted mutants, and complemented strain (CA).
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Figure 5-5. Northern-blot hybridization indicates that the ∆tsf1-disrupted mutants failed to accumulate the EfPKS1 and reduce production of RDT1, PRF1 and EfHP1 transcripts. Ethidium bromide-stained rRNA indicates the relative loading of the samples. Total RNA was isolated from fungal strains grown on potato dextrose agar under continuous light for 7 days, electrophoresed in formaldehyde-containing gels, blotted onto nylon membranes and hybridized to the probes as indicated at 50 °C.
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Figure 5-6. Northern-blot hybridization indicates a feedback inhibition of the ESC clustering genes in Elsinoë fawcettii. Expression of the EfHP1, RDT1, TSF1, PRF1, and ECT1 genes in the EfPKS1 disrupted mutant, D4, was dramatically repressed. Functional complementation by introducing a copy of EfPKS1 into a null mutant yielded two fungal strains (C1 and C2) with a restored gene expression. Total RNA was isolated from fungal strains grown on potato dextrose agar under continuous light for 7 days, electrophoresed in formaldehyde-containing gels, blotted onto nylon membranes and hybridized to the probes as indicated. Ethidium bromide-stained rRNA is shown to indicate the relative loading of the samples.
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Figure 5-7. Hypothetical reaction pathway for the formation of elsinochromes (ESCs) by function of the ESCs biosynthetic clustering genes. The TSF1 transcription factor is proposed to regulate expression of the clustered genes. The early precursors (acetyl-CoA and Malonyl-CoA) are incorporated into a growing polyketide chain, which is released and cyclized by the function of EfPKS1 as stated in the text. The products of RDT1 and OXR1, are thought to be required for post-polyketide-synthesis steps, whereas the actual function of PRF1 remains unknown. ECT1 is assumed to be responsible for ESC exportation.
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Figure 5-8. Hypothetical signal transduction and regulatory controls for ESC biosynthesis and accumulation. The biosynthetic pathway is assumed to be mainly regulated by pathway-specific transcriptional regulator, TSF1, that is presumably activated by a wide range of global regulatory factors in response to various environmental cues as described in text.
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CHAPTER 6 GENETIC AND PATHOLOGICAL DETERMINATIONS OF Elsinoë fawcettii FIELD
ISOLATES FROM FLORIDA
Elsinoë fawcettii, the causal pathogen of citrus scab, induces superficial corky lesions on
the affected tissues. Production of elsinochrome (ESC) phytotoxins has been shown to play an
essential role for E. fawcettii virulence and lesion development. In this study, 52 field-collected
E. fawcettii isolates from Florida citrus growing areas were examined for ESC production and
pathogenicity to three index citrus hosts: rough lemon, grapefruit, and sour orange. All
pathogenic isolates were found to produce ESCs in cultures and/or in planta, further confirming
the important role of ESCs in fungal virulence. Several field-collected isolates of E. fawcettii
displayed different pathogenicity, host range, and ESC production, apparently differing from the
other isolates. One field isolate, Ef41, was completely non-pathogenic to rough lemon, grapefruit,
and sweet orange, and did not produce ESCs. Ef41 failed to express the EfPKS1 gene and
differed considerably from other E. fawcettii isolates on the basis of phylogenetic analysis
inferred from ITS region. Moreover, as assays on detached rough lemon and grapefruit leaves,
co-inoculation of a low virulence isolate attenuated disease severity caused by the highly virulent
isolate.
Introduction
Citrus scab caused by Elsinoë fawcettii is widely distributed in humid citrus-growing areas
worldwide. The development of superficial corky lesions induced by this pathogen leads to a
significant economic loss for the fruit intended for fresh market. Many phytopathogenic Elsinoë
species have been reported to produce elsinochromes (ESCs) (reviewed by Weiss, et al. 1987).
Limited work has been done to demonstrate the linkages between ESC production and fungal
pathogenesis. ESCs presumably react with oxygen upon illumination and generate superoxide
and singlet oxygen, which have been previously shown to be highly toxic to cells and tissues of
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citrus and tobacco (Liao and Chung 2008a). Furthermore, the non-ESC producing E. fawcettii
mutants, derived from disruption of the EfPKS1 gene, exhibited a reduced virulence to citrus
(Liao and Chung 2008b), further confirming the important role of ESCs in fungal pathogenesis.
However, ESC toxins have never been isolated from Elsinoë-induced lesions. Elsinoë species or
Elsinoë fawcettii isolates are not readily distinguishable by morphological traits (M. Priest
unpublished data; Fantin 1988; Fortes, 1989; Timmer et al. 1996). Molecular approaches such as
restriction analysis of the amplified internal transcribed spacer (ITS) of ribosomal DNA digested
with several endonucleases and sequence analysis of the ITS have been applied to differentiate
the closely related species of Elsinoë, such as E. fawcettii, E. australis, and Sphaceloma fawcettii
var. scabiosa (Tan et al. 1996). The internal transcribed spacer 1 (ITS 1) between 18S rDNA and
5.8S rDNA is relatively less conserved among species, and has been demonstrated to be a useful
marker for differentiating inter-relationships of fungal strains, species, and genera (Duncan et al.
1998; Brookman et al. 2000). For E. fawcettii, the random amplified polymorphic DNA (RAPD)
technique has been proven as a useful and easy tool for identifying Elsinoë species and the
isolates from different geographic areas (Tan et al. 1996). In Florida, two pathotypes of E.
fawcettii: Florida Broad Host Range (FBHR) and Florida Narrow Host Range (FNHR) have been
described on the basis of host range (Whiteside 1978; Timmer et al. 1996). The FBHR pathotype
primarily affects the leaves and fruit of grapefruit (C. paradisi Macf.), lemon (C. limon (L.)
Burm. F.), rough lemon (C.jambhiri Lush), Murcott and Temple tangors (C. sinensis (L.) Osbeck
x C. reticulata Blanco) and sour orange (C.aurantium L.), and the fruit of sweet orange (C.
sinensis). By contrast, the FNHR pathotype affects all of the above except sour orange, Temple
tangor, and sweet orange. Except for differences in host range, FBHR and FNHR pathotypes are
not distinguishable morphologically and genetically.
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In the present study, I surveyed 52 E. fawcettii isolates from citrus groves in Florida and
found that many of the isolates accumulated red or orange pigments in culture. In this chapter,
close relationships between fungal virulence and ESC production in vitro and in planta were
elucidated. Investigation of their host ranges and taxonomic relationships among isolates of E.
fawcettii suggests the presence of novel pathotypes or phylogenetic species of E. fawcettii in
Florida.
Materials and Methods
Fungal Isolates and Growth Conditions
All fungal isolates of Elsinoë fawcettii Bitancourt & Jenkins (anamorph: Sphaceloma
fawcettii Jenkins) were collected from citrus-growing areas in Florida and were kindly provided
by L. W. Timmer (University of Florida). The origins of these isolates are indicated in Table 6-1.
Fungal isolates were maintained on potato dextrose agar (PDA, Difco, Sparks, MD) under
constant fluorescent light at 25 °C. Other media used in this study include a complete medium
(CM) containing 1 g Ca(NO3)2·4H2O, 0.2 g KH2PO4, 0.25 g MgSO4·7H2O, 0.15 g NaCl, 10 g
glucose, 1 g yeast extract, and 1 g casein hydrolysate per liter (Jenns et al. 1989), and a 10%
skim milk medium (Difco). For ESC production, fungal isolates were grown on thin PDA plates
(5 mL in 100 x 15 mm Petri dish plates) for 10 days under light. Fungal isolates were grown on
agar plate overlaid with a piece of sterile cellophane when DNA or RNA isolation was desired.
Extraction and Analysis of Elsinochromes (ESCs)
ESC toxins were extracted from fungal cultures and analyzed by TLC as described in
Chapter 2. Quantitative analysis of ESC produced in vitro was performed by extracting agar
plugs with fungal hyphae with 5 N KOH and measuring absorbance at 480 nm. To extract ESCs
from affected rough lemon leaves, leaf spots with necrotic lesions were cut, pooled, and
extracted twice with ethyl acetate at 4 °C for 16 h in the dark. Organic solvent was collected, air-
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dried at room temperature, suspended in small volumes of acetone, and analyzed by
spectrophotometry at A480 and TLC. The concentration of ESCs was calculated by reference to a
regression line that was established using pure cercosporin (Sigma-Aldrich) as standard and was
expressed as cercosporin equivalents.
Production and Germination of Conidia
Conidia were prepared by the method described by Timmer and colleagues (1996) with
modifications. Approximately, 0.03 g of fungal hyphae was ground with a disposable pestle in 4
mL Fries medium (Fries, 1978), placed on a Petri dish (15 x 90 mm), and incubated at 25 °C for
2 days in the dark to trigger conidial formation. Plates were washed with sterile, distilled water,
flooded with distilled water (pH 7.0) and incubated for additional 12-15 hr in the dark. Conidia
on the bottom of the plate were washed once with distilled water, scraped, re-suspended after
centrifugation (6000 rpm, 10 min), and passed through a filter to remove mycelia. Conidia were
counted and measured with the aid of a hemocytometer using a microscope at x 200
magnification. Germination of conidia was determined 2 days post inoculation on detached
rough lemon and grapefruit leaves as described below and was calculated in proportion to the
total number of conidia recovered from the inoculated spot.
Pathogenicity Assays
Assays for fungal pathogenicity were conducted on detached rough lemon (Citrus jambhiri
Lush), grapefruit (Citrus paradisi), and sour orange (Citrus aurantium) leaves inoculated with
conidial suspension. Rough lemon is susceptible to all Elsinoë pathotypes of citrus (Timmer et al.
1996). Conidial suspension (1μL, 1 x 105 mL-1) was carefully placed on the leaf surface and the
inoculated leaves were incubated in a mist chamber under constant fluorescence light for lesion
formation.
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Enzymatic Activity Assays
Assays for enzymatic activities were determined as described (You and Chung 2007).
Glucose in the complete medium (CM) was substituted by appropriate carbon sources (1% citrus
pectin, pH4.5 or pH7.6; 1% polygalacturonic acid, pH4.5 or pH7.6; 0.5% carboxymethyl
cellulose; 10 g glucose plus 0.1% 16-hydroxyhexodecanoic acid (cutin monomer)) for induction
of the respective enzyme. Skin milk used for proteolytic activity assays was prepared by mixing
(3:22, v:v) solution A (10% skim milk dissolved in 0.05 M phosphate buffer, pH 6.8) and
solution B (Agar medium containing 0.23% yeast nitrogen base) after sterilization.
Extracellular activities CWDEs (cell wall degradation enzymes) were evaluated by
measuring the amounts of reducing sugar that was released from 1% polygalacturonic acid
(PGA), 1% citrus pectin or 0.5% carboxymethyl-cellulose (CMC) and reacted with
dinitrosalicylic acid (DNS) reagent under alkaline conditions (Bailey et al. 1993). Fungal isolates
were grown on a modified CM in which glucose was substituted by an appropriate
polysaccharide for 10 days. Five 5-mm agar plugs bearing fungal mycelia were cut and placed in
0.1M sodium phosphate buffer containing 1% PGA (pH 4.5 or pH 7.6), 1% citrus pectin (pH 4.5
or pH 7.6), or 0.5% CMC (pH 5). After incubation at 50 °C for 1 hour, an equal volume of DNS
reagent was added, boiled at 95 °C for 5 min, and absorbance was measured at A540nm. The
regression line and correlation coefficient (r2 > 0.98) were established using glucose as a
standard. One unit of enzyme activity is defined as 1 nmole of glucose liberated from the
substrate per minute.
Extracellular cutinase activities were determined by formation of a yellow color after
reacting with 50 mM paranitrophenyl butyrate (PNPB) in 0.1M sodium phosphate buffer (pH 5)
for 1 hour and measured at A405nm (Stahl and Schäfer 1992). Fungal isolates were grown on a
modified CM containing 0.1% 16-hydroxyhexadecanoic acid (HHDA, dissolved in 1% sodium
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acetate) as a sole carbon source for 8 days for induction before the enzymatic assays. One unit of
cutinase released is 1 nmole p-nitrophenol produced per minute.
Proteolytic activities were determined by formation of clear zones on 10% skim milk
plates. Fungal mycelia were ground in sterile water, and spread onto an agar plate. After
incubation at 28 °C for 4 days, the sizes of clear zones were measured.
PCR-Restriction Fragment Length Polymorphism (RFLP) and Sequence Analysis of ITS and β-tubulin Genes
The ITS regions of fungal rDNA were amplified by PCR with primer ITS 1 (5’-
TCCGTAGGTGAACCTGCGG-3’) and ITS 4 (5’-TCCTCCGCTTATTGATATGC-3’) as
described by White et al. (1990). A 600-bp DNA fragment, encompassing entire ITS 1, 5.8S and
partial 18S of rDNA, was amplified. Partial β-tubulin gene (~ 500 bp) of fungal isolates were
amplified with primer sets Bt1R (5’-GACGAGATCGTTCATGTTGAACTC-3’) and Bt1F (5’-
TTCCCCCGTCTCCACTTCTTCATG-3’) as described (Glass and Donaldson 1995). The PCR
amplification reactions were carried out in a Peltier thermal cycler (MJ. Research, INC.,
Watertown, MA). The DNA was amplified by GoTaq® Flexi DNA polymerase (Promega, WI)
in 50 μL reaction containing 0.2 µM of each of the primer set and 50 ng of genomic DNA.
Thermal cycling parameters for amplification of both ITS and β-tubulin include a single cycle of
95 °C for 2 min, followed by 35 cycles of 45 sec at 95 °C, 45 sec at 56 °C, and 1 min at 72 °C
and a final step at 72 °C for 5 min. The amplified DNA fragments were digested with 4-bp
recognition sequence restriction endonucleases, electrophoresed in 2% agarose gel, stained with
ethidium bromide, visualized, and photographed under ultraviolet light. The amplified ITS
fragments were cleaved with HaeIII, MspI, or TaqαI, whereas the amplified β-tubulin gene
fragments were cut with AluI, DpnI, HaeIII, MspI, NlaIV, or TaqαI. For direct sequencing, the
DNA fragments were amplified by an Expand High Fidelity PCR system (Roche Applied
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Science). Otherwise, all fragments were cloned into pGEM-T easy vector (Promega, Madison,
WI) for sequencing analysis from both directions at Eton Bioscience (San Diego, CA). Similarity
was determined by Emboss MATCHER Program (Sanger Institute, Hinxton, Cambridge, UK.).
The ITS 1 sequences were aligned with published sequences and phylogenetic analyses were
performed using DS Gene v2.5 program (Accelrys Inc., San Diego).
Random Amplified Polymorphic DNA (RAPD)
RAPD fragments were amplified with a 10-mers primer, OPX-7 (5’-GAGCGAGGCT-3’),
OPX-13 (5’-ACGGGAGCAA-3’), or MtR 1 (5’-GTAAAGGGGG-3’), by Taq DNA polymerase
(GenScript, Piscataway, NJ). The cycling profile for amplification includes an initial cycle of 94
°C for 3 min, immediately followed by 35 cycles of 94 °C for 30 sec, 36 °C for 45 sec, 72 °C for
4 min and a final step of 72 °C for 7 min. The amplified DNA fragments were separated by
electrophoresis in 2% agarose gel.
Miscellaneous Methods of Processing Nucleic Acids
Plasmid DNA was purified using a Wizard DNA purification kit (Promega) from
transformed Escherichia coli DH5α bacterial cells. Fungal RNA was extracted with Trizol
reagent (Invitrogen, Carlsbad, CA). Standard procedures were used for electrophoresis and
Northern-blot hybridization. DNA probes used for hybridization were labeled with digoxigenin
(DIG)-11-dUTP (Roche Applied Science) by PCR with gene-specific primers. The
manufacturer’s recommendations were followed for probe labeling, hybridization, post-
hybridization washing and immunological detection of the probe using a CSPD
chemofluorescent substrate for alkaline phosphatase (Roche Applied Science).
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Results
Morphological Examination
Isolates of Elsinoë fawcettii were first examined for potential morphological variations
using light or dissection microscopes. All isolates produced filamentous mycelia, and formed
nodular/bulbous mycelia after a prolonged incubation (e.g., Fig. D-1). Pleomorphic colonies
were observed among isolates when cultured on PDA or CM culture (Fig. D-2 and data not
shown). All isolates had a limited mycelial extension, which were slightly raised in the center.
Some isolates (e.g., Ef12, Ef17, Ef29, Ef37, and Ef48) produced colonies that were dark red with
a little fluffy velvet-like mycelia, while others produced pale colonies (e.g., Ef30 and Ef49)
covered with or without fluffy mycelia. All isolates produced hyaline conidia, showing elliptical
to obclavate, and nonseptate cells (data not shown). The isolate Ef41 produced smaller conidia
having the means size of 3.4 x 1.9 µm (length x width), while other isolates produced conidia
with the mean size 4.1-5.1 x 2.2-2.7µm (length x width).
Pathogenicity Assays
As rough lemon is susceptible to all Elsinoë spp. (Timmer et al. 1996), fungal
pathogenicity was primarily evaluated in this citrus cultivar. In total, 52 E. fawcettii isolates
cultured from different citrus cultivars and geographic locations of citrus-growing areas in the
state of Florida were evaluated for pathogenicity on detached rough lemon leaves (Table 6-1).
All isolates produced substantial numbers of conidia, ranging from 0.1-50 x 106 conidia per mL.
As assayed on detached rough lemon leaves, all isolates except one (Ef41) incited necrotic
lesions on young leaves (7-10 days after flushing) and exhibited a reduced virulence to varying
degrees when inoculated onto older leaves (14-18 days after flushing, data not shown). Isolate
Ef41 failed to induce any necrosis on rough lemon, while isolates Ef10 and Ef29 had a weak
virulence on rough lemon. Pathogenicity of nine isolates (Ef10, 12, 17, 29, 30, 37, 41, 48, and 49)
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was also assessed after inoculation onto detached grapefruit and sour orange leaves (Table 6-1).
Isolates Ef10 and Ef29 were weakly virulent to either grapefruit or sour orange and isolate Ef41
was nonpathogenic to either citrus cultivar. Other isolates were weakly or moderately virulent to
grapefruit or sour orange (Table 6-1).
Production of ESC Toxin in Culture
ESCs produced by E. fawcettii isolates was extracted from agar plugs bearing fungal
mycelium with 5N KOH and quantified by measuring absorbance at 480 nm. As shown in Table
6-1, production of ESC toxins was variable among isolates, ranging from 1.4 to 16.6 nmoles per
agar plug. Noticeably, several isolates (Ef1, 15, 25, 26, 27, and 47) produced little or no ESCs in
axenic cultures despite being pathogenic to rough lemon. i.e., there was no relationship between
in-vitro production of ESCs and lesion formation on rough lemon.
Extraction of ESCs from Scab Lesions
To determine if ESCs were accumulated during fungal colonization, 23 field isolates of E.
fawcettii, including five isolates (Ef1, 25, 27, 41and 47) that produced no ESCs in cultures, were
inoculated onto detached rough lemon leaves. ESCs were then extracted from a pooled sample of
20 necrotic lesions of each isolate, and analyzed by TLC. ESCs with different banding profiles
and intensities were extracted from lesions induced by 22 isolates tested (Fig. 6-1). Isolate Ef41
did not incite any visible lesions on rough lemon leaves and accumulated no detectable ESCs.
Isolates Ef1, Ef25, Ef27and Ef47 produced no detectable levels of ESCs in cultures, but
apparently produced ESCs in planta and induced characteristic scab lesions on rough lemon
leaves (Fig. 6-1; Table 6-1). Judging from band width and intensity, band 1 (Rf 0.68) appeared to
be the major compound of the leaf extracts, whereas band 3 (Rf 0.22) was the most abundant
product of the cultural extracts. Spectrophotometric scanning indicated that the acetone extracted
pigments from scab lesions on rough lemon leaves displayed a strong absorbance at 460 nm with
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two minor peaks at 530 and 570 nm, resembling those purified from E. fawcettii cultures as
described in Chapter 2.
Further Characterization of a Nonpathogenic Elsinoë fawcettii Isolate
In addition to assays for fungal pathogenicity and ESC production, nine E. fawcettii
isolates, representing nonpathogenic (Ef41), weakly virulent (Ef10, Ef17, Ef29, and Ef49) and
highly virulent isolates (Ef12, Ef30, Ef37, and Ef48), were further examined for potential genetic
variations. As shown in Table 6-1, isolates that were pathogenic to rough lemon were also
pathogenic to grapefruit. All isolates except Ef41 produced scab pustules on young leaves (7
days after flushing) of rough lemon and grapefruit and exhibited a reduced virulence to varying
degrees on older leaves (14 days after flushing). These nine E. fawcettii isolates were not all
pathogenic on sour orange. Only three isolates, Ef12, Ef17, and Ef48, of nine isolates produced
severe pustule lesions on sour orange.
Alterations in Hydrolytic Enzyme Activities
To determine if fungal hydrolytic enzymes are required for pathogenicity of E. fawcettii,
the extracellular activities of proteolytase, cellulase, pectinase, polygalacturonase and cutinase
were determined among nine isolates described above. Isolate Ef41 had no detectable proteolytic
activity, whereas isolates Ef10, Ef17, Ef29, and Ef49 with lower virulence had lower proteolytic
activity compared to the pathogenic isolates Ef12, Ef30, Ef37, and Ef48 (Fig. 6-2A). Similarly,
isolates Ef12, Ef30, Ef37, and Ef48 displayed higher cellulase activity than other isolates tested
(Fig. 6-2B). All E. fawcettii isolates tested exhibited high levels of pectolytic activities when
grown in a medium containing citrus pectin as a sole carbon source (pH 4.5), but the overall
pectolytic activities decreased considerably at pH 7.6 (Fig. 6-2C). When grown in a medium
containing polygalacturonic acid as a sole carbon source, all isolates had no or little
polygalacturonase activity when the medium was buffered to pH 7.6. By contrast, isolate Ef41
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exhibited marked polygalacturonase activity when the medium was buffered to pH 4.5 (Fig. 6-
2D). There was no significant difference in cutinase activities among all isolates tested, despite
that isolate Ef41 showed slightly but not significantly lower cellulase activity (Fig. 6-2E).
Production of ESC and Expression of the EfPKS1 gene in the Nonpathogenic Isolate (Ef41)
Of 52 isolates examined, only Ef41 isolate failed to infect rough lemon, grapefruit, or sour
orange and produced no ESC either in culture or in planta (Table 6-1). Thus, expression of the
polyketide synthase-coding gene, EfPKS1, that has been shown to be required for ESC
biosynthesis (Liao and Chung, 2008b) was examined in Ef12 and Ef41 isolates by Northern blot
analysis.
As shown in Fig. 6-2F, accumulation of the EfPKS1 transcript was normal in the ESC-
producing isolate Ef12. The EfPKS1 gene transcript was undetectable in isolate Ef41, which may
account for no ESC production.
Co-inoculation of Two E. fawcettii Isolates Reduces Lesion Formation
To test if the isolates with low virulence will compete with the isolates with high virulence,
various combinations of two E. fawcettii isolates were co-inoculated onto detached rough lemon
and grapefruit leaves and lesion formation was assessed.
Co-inoculation of conidial suspension of isolate Ef12 with either isolate Ef29 or Ef49
resulted in a repressed symptom development on both citrus cultivars compared to those
inoculated with the Ef12 isolate alone (Fig. 6-3). When isolate Ef12 alone was inoculated onto
rough lemon or grapefruit, over 65% of the total spots inoculated developed severe scab lesions
covered with numerous pustules (level 4-5). When isolate Ef12 was co-inoculated with isolate
Ef29 or Ef49, less than 14% of the inoculated spots on either rough lemon or grapefruit leaves
developed severe scab lesions. Co-inoculation of isolate Ef12, Ef29 or Ef49 with isolate Ef41 did
not alleviate symptom development (Fig. 6-3).
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Molecular Evaluation of E. fawcettii Isolates
E. fawcettii isolates cultured from Florida citrus growing areas displayed variations in
virulence to rough lemon, grapefruit, and sour orange and ESC production. To determine if such
variations also occur at the genetic level, molecular approaches, including PCR-RFLP, RAPD,
and sequence analysis of internal transcribed spacer (ITS) region and the conserved gene (β-
tubulin), were used to further characterize E. fawcettii isolates with differ virulence.
As assessed by PCR-RFLP of the amplified ITS rDNA fragment (~600 bp) cleaved with
either HaeIII, MspI, or TaqαI, isolate Ef41 apparently had DNA banding profiles that were
clearly distinguishable from those of other isolates tested (Fig. 6-4). Polymorphisms of the
amplified β-tubulin gene fragments digested with HaeIII or TaqαI, also separated isolate Ef41
from other E. fawcettii isolates (Fig. 6-5). The amplified tubulin cleaved with AluI, DpnI, MspI,
or NlaIV resulted in similar profiles among E. fawcettii isolates (Fig. 6-5). Furthermore, isolate
Ef41 was apparently different from other E. fawcettii isolates when randomly amplified DNA
fragments using a 10-mer primer OPX-7, OPX-13, or MtR 1 were compared (Fig. 6-6).
The amplified ITS 1 region from isolates Ef12, Ef29, Ef41, and Ef49 was sequenced and
compared with the published sequences in the database (National Center for Biotechnology
Information) to determine their phylogenetic relationships. The ITS sequences obtained from
isolates Ef29 and Ef49 were identical, showing 100% identity, while Ef12 had 90% identity to
those of E. fawcettii (EFU28058) and Sphaceloma fawcettii (SFU28059). Isolate Ef41 displayed
lowest ITS sequence similarity and apparently was separated from other E. fawcettii isolates of
citrus (Fig. 6-7). Furthermore, partial β-tubulin gene sequences of isolates Ef12 and Ef41 were
compared with the published sequences in the database. The relative identity of fragments is
shown in Table 6-2, indicating that isolate Ef41 shared higher nucleotide identity with isolate
Ef12 (85.8%), whereas Ef12 displayed varying similarity of β-tubulin gene sequence to other
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fungi including Aspergillus nidulans (88.9%), Cercospora beticola (87.0%), Mycosphaerella
graminicola (86.7%), Neurospora crassa (90.1%), and Neosartorya fischeri (87.7%) (Table 6-2).
Discussion
ESCs produced by E. fawcettii, due to the production of toxic oxygen species upon
irradiation, have been shown to be highly toxic to the cells and tissues of citrus and tobacco
(Liao and Chung 2008a) and also essential for full virulence of E. fawcettii (Liao and Chung
2008b). Analysis of ESC production and fungal pathogenicity on three index hosts of citrus
(rough lemon, grapefruit, and sour orange) revealed a marked variation among E. fawcettii
isolates cultured from Florida. Evidence presented in this study indicated that the majority of E.
fawcettii isolates produced ESCs in axenic culture (~90%, Table 6-1), but the production was
varied widely with isolate.
All E. fawcettii isolates that were pathogenic to rough lemon produced ESCs in culture
and/or in planta, in spite of lacking of a relationship between the amounts of ESCs accumulated
in culture and in planta. The amounts of ESCs produced by an individual fungal isolate in
culture or in planta did not account for the severity of scab disease induced by the same isolate.
A survey of 52 isolates revealed that four isolates (Ef1, Ef25, Ef27, and Ef47) accumulated no
detectable level of ESCs in culture, but provoked characteristic scab lesions and accumulated
substantial amounts of ESCs in rough lemon leaves, implicating the presence of signals or
substrates from the plant for ESC production. The Ef41 isolate that was not pathogenic to rough
lemon, grapefruit, or sour orange, was unable to produce any detectable ESCs. Since ESCs are
extremely toxic upon reaction with oxygen molecules under light, this study further confirmed
the critical role of ESCs for lesion formation and fungal pathogenesis, consistent with the
previous finding from molecular analysis (Liao and Chung 2008b). As all pathogenic E. fawcettii
isolates produced varying amounts of ESCs in planta, it is tempting to speculate that a trace
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amount of ESCs, continuously produced by the pathogen, might be sufficient to facilitate fungal
invasion and colonization to its hosts.
The occurrence of citrus scab on various citrus species and cultivars has been reported in
different countries of the world, primarily based on field observation. Yet, little study has been
done toward delineating the host range and distribution of the species and pathotypes of citrus
scab fungi. The “Florida Broad Host Range (FBHR) and the “Florida Narrow Host Range
(FNHR)” described in Florida based on host range are not distinguishable genetically (Whiteside
1988; Timer et al. 1996). A recent study described a novel E. fawcettii pathotype that was only
pathogenic to Natsudaidia (C. natsudaidai Hayata) and Kinkoji (C. obovoidea Hort ex Tak.) fruit
in Korea (Hyun et al. 2001).
As is evident from the present study, it seems likely that additional pathotypes or new
species of Elsinoë might be present in Florida citrus-growing areas other than FBHR and FNHR.
The Ef10 and Ef29 isolates, originally cultured from infected SunCha Shakat mandarin and
Swingle citrumelo, respectively, were only weakly virulent to grapefruit, rough lemon, and sour
orange. The Ef17 isolate, originally cultured from infected Temple leaves, appeared to be highly
virulent to sour orange, yet induced moderate or mild scab lesions on rough lemon and grapefruit.
The Ef12 isolate was highly virulent to the three citrus hosts tested, but displayed low similarity
of the ITS 1 sequence to those of E. fawcettii. The Ef41 isolate, also cultured from infected
Temple leaves, was apparently different from other field isolates, in terms of pathogenicity,
morphology, toxin production, phylogenic variations, and other genetic variations and thus,
likely represents a novel phylogenic or biological species. Although the Ef41 isolate failed to
attack the leaves of three index citrus cultivars, it does not necessarily indicate that Ef41 is an E.
fawcettii saprophyte. Similar pathotypes that were nonpathogenic to rough lemon, grapefruit, and
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sour orange have also been reported from field-collected isolates in Argentina (Timmer et al.
1996). However, the Argentina isolates had different ITS RFLP banding profiles from that of
Ef41 isolate. Since only a limited number of isolates were tested in this study, it is impossible to
conclusively determine if Ef41, Ef29, and Ef49 are different pathotypes of E. fawcettii or simply
represent novel cryptic Elsinoë species that have not yet been characterized in citrus. More field
isolates need to be tested and a broader range of citrus cultivars are required to be inoculated to
understand the complexity of all of the pathotypes of E. fawcettii in Florida.
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Table 6-1. Pathogenicity and production of elsinochromes (ESCs) in vivo and in planta by different field isolates of Elsinoë fawcettii
Fungal isolates (No. and names)
Disease severity2 detached-leaf
ESC production (nmole per plug or spot)
# (Ef) Name
Origins1
RL GF SO In vitro3 In planta4 1 Duda-Imk-1 Temple +++ nd5 nd 0 0.52 Duda-Imk-2 Temple ++++ nd nd 3.0 ± 1.3 nd3 Duda-Imk-5 Temple ++++ nd nd 8.8 ± 0.4 nd4 Eus-1 Murcott +++++ nd nd 3.2 ± 1.2 nd5 Eus-2 Murcott +++ nd nd 1.8 ± 0.6 nd6 Eus-3 Murcott +++++ nd nd 1.6 ± 0.2 nd7 Eus-4 Murcott +++ nd nd 2.6 ± 0.2 nd8 Lkpcd-2 Temple +++++ nd nd 4.0 ± 0.6 nd9 Navarro-3 Grapefruit +++++ nd nd 5.0 ± 0.2 8.910 Scsk Sun Shu Shakat +/- + + 12.6 ± 3.0 011 Navarro-6 Grapefruit +++++ nd nd 6.2 ± 0.2 11.612 FtPierce-3a Temple ++++ ++ +++ 6.4 ± 3.0 nd13 FtPierce- 4b Temple +++ nd nd 5.6 ± 0.6 nd14 FtPierce-3 Temple +++ nd nd 6.8 ± 1.2 nd15 Carrizo Carrizo citrange +++ nd nd 0.2 ± 0.0 0.916 Irrec-3 Murcott +++ nd nd 5.6 ± 1.6 nd17 R-36 Temple + ++ ++++ 1.4 ± 0.0 1.118 Labelle Lemon ++ nd nd 16.6 ± 1.2 nd19 Ftmead4 Grapefruit ++++ nd nd 5.6 ± 0.6 nd20 Duda-Imk-3 Temple ++++ nd nd 4.4 ± 0.7 nd21 Ss-Imk-3 Temple ++++ nd nd 3.0 ± 0.6 nd22 Ss-Imk-1 Temple ++++ nd nd 5.8 ± 0.6 2.223 Tbl-La-2 Temple ++++ nd nd 6.2 ± 0.8 6.024 Rl-2 Rough lemon ++++ nd nd 7.8 ± 0.8 4.625 Russel-15 Temple +++++ nd nd 0 2.926 Smoak 1 Temple +++++ nd nd 0.7 ± 0.2 7.727 Ss Imk 1 Tahiti lime +++++ nd nd 0 2.628 Stl-Lv-d Temple +++ nd nd 6.2 ± 1.2 1.729 Citro-1 Swingle citrumelo +/- + +/- 2.6 ± 0.6 0.930 Eus-Lv-1 Murcott ++++ ++++ +/- 3.8 ± 0.4 nd31 Eus-1 Temple ++ nd nd 7.9 ± 0.8 nd32 Ftmead 3 Grapefruit +++++ nd nd 3.0 ± 0.4 nd
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Table 6-1. (Continued) Fungal isolates (No. and names)
Disease severity2 detached-leaf
ESC production (nmole per plug or spot)
# (Ef) Name
Origins1
RL GF SO In vitro3 In planta4 33 FtPierce-1 Temple +++++ nd nd 5.4 ± 0.8 nd34 FtPierce-4c Temple +++++ nd nd 5.8 ± 0.6 nd35 Imk-Br-1a Grapefruit +++ nd nd 5.2 ± 0.8 nd36 Imk-Br-1b Grapefruit +++ nd nd 5.6 ± 0.4 nd37 Imk-Br-1c Grapefruit ++++ ++++ +/- 6.2 ± 1.2 nd38 Imk-br-2 Grapefruit +++ nd nd 5.2 ± 0.6 nd39 SWFREC-Lv-1 Murcott ++++ nd nd 5.2 ± 0.6 4.940 Imk-Br-3a2 Grapefruit +++ nd nd 3.8 ± 0.8 nd41 SWFREC- Imk-1 Temple - - - 0 042 Imk-Br-3c Grapefruit +++ nd nd 3.2 ± 0.4 2.643 Tbl-La-1 Temple ++++ nd nd 6.4 ± 0.4 7.944 Imk-Br-3e Grapefruit +++ nd nd 7.2 ± 0.2 nd45 Imk-Br-4d Grapefruit +++ nd nd 5.6 ± 0.4 nd46 Lefond b Grapefruit +++ nd nd 6.0 ± 1.4 nd47 Lefond d Grapefruit +++ nd nd 0 1.148 Manatee w-2 Temple ++++ +++ ++++ 5.2 ± 0.6 nd49 Cbl-Wh-1 Unknown ++ ++ +/- 6.5 ± 0.4 1.250 Manatee w-5 Temple ++++ nd nd 5.0 ± 0.2 4.751 Avonpark m2 Unknown ++++ nd nd 5.8 ± 0.6 7.552 Avonpark m3 Unknown ++++ nd nd 4.8 ± 0.6 2.1
1Citrus species or cultivars (Citrus spp.). Temple (C. temple), Murcott (C. reticulate x C. sinensis), Grapefruit (C. paradisi), Sun Shu Shakat (C. sinesis), Carrizo citrange (C. sinensis x Poncitrus trifoliate), Lemon (C. limon), Rough lemon (C. jambhiri), Tahiti lime (C. aurantifolia), Swingle citrumelo (C. paradisi x P. trifoliata), sour orange (C. aurantium). 2Pathogenicity assays were performed on detached leaves (7-10 days after flushing) inoculated with conidial suspension (1 x 105 mL-1). Inoculated leaves were kept in a moist chamber under constant florescent light for 15 days. Disease severity was rated on a scale, - for no lesion formation; +/-, chlorotic reaction only, no scab pustules; +, lesions with minor necrosis, and +++++, lesions with severe necrosis. RL, rough lemon; GF, grapefruit; SO, sour orange. 3Fungal isolates were cultured on PDA under constant light for 10 days and elsinochromes (ESCs) were extracted with 5N KOH and measured at A480. Data are the means and standard errors of four replicates containing 12 agar plugs of each sample. 4Conidial suspension was inoculated onto detached rough lemon leaves and incubated for 14 days. In total, 20 spots (2-mm in diameter) were cut from various leaves, pooled, and soaked in ethyl acetate. ESCs were separated on TLC plate (Fig. 6-1) and quantified using a regression line established with known concentrations of ESCs and cercosporin. 5nd, not determined
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Table 6-2. Sequence identity (%) of fungal partial β-tubulin gene Fungus1 Ef12 Ef41 AN CB MG NC NF SS VD EF12 - 85.82 88.9 87.0 86.7 90.1 87.7 75.0 76.0 EF41 - - 84.1 84.5 84.5 85.0 82.6 71.0 74.1 AN - - - 87.7 85.2 90.8 92.5 75.4 76.3 CB - - - - 88.1 88.1 88.1 74.2 74.2 MG - - - - - 86.7 85.5 74.0 73.8 NC - - - - - - 89.1 77.5 79.9 NF - - - - - - - 75.8 75.7 SS - - - - - - - - 80.3 VD - - - - - - - - -
1Partial β-tubulin genes of Elsinoë fawcettii isolates Ef12 and Ef41 were amplified and sequenced. Partial β-tubulin genes from other fungi were obtained from Genbank with accession numbers. AN, Aspergillus nidulans (XM_653694); CB, Cercospora beticola (AY856373); MG, Mycosphaerella graminicola (AJ310917); NC, Neurospora crassa (XM_952576); NF, Neosartorya fischeri (XM_001264677); SS, Sclerotinia sclerotiorum (AY12374); VD, Verticillium dahliae (DQ266135)
2Nucleotide identity (%) was analyzed by emboss MATCHER program (Sanger Institute, Hinxton, Cambridge, UK.). Approximately, 485-bp sequences from each organism were aligned and compared for identities (Fig. D-3).
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Figure 6-1. Thin-layer chromatography analysis (TLC) of ESC phytotoxins (the red/orange
pigments) extracted from affected rough lemon leaves inoculated with different isolates of Elsinoë fawcettii. Fungal isolates were inoculated onto detached rough lemon leaves and incubated for 15 days for lesion development in a moist chamber. Leaf lesions were pooled and soaked in ethyl acetate. ESCs were recovered by suspending in small volumes of acetone and separated on TLC plates with a solvent system containing chloroform and ethyl acetate (1:1, v:v). ESCs extracted from cultural filtrate (C) of CAL WH-1 isolate showing five distinct bands at Rf as indicated were used as positive controls (Chapter 2), whereas negative controls were the extracts of rough lemon leaves (L) inoculated with water only. Fungal isolates that did not produce detectable ESCs in culture are circled.
147
Figure 6-2. Determination of extracellular enzyme activities: A) proteolysase; B) cellulase; C) pectolytic activities (mainly pectin lyase, pH 4.5 and pectin methyl esterase, pH 7.6); D) pectolytic activities (primarily endo- and exo-PGs, pH 4.5 and pectate lyase, pH7.6); and E) cutinase by Elsinoë fawcettii isolates. Fungal isolates were grown on CM with inducers [5% skim malk; 0.5% CMC; 1% PG; 1% citrus pectin, or 0.1% HHDA] as appropriate for 4-10 days and enzymatic activities were measured either by diameter of clear zone (proteolytic activity) or by spectrophotometry after reaction with appropriate chromogens (cellulase, pectolytic, and cutinase activities). Each column represents the mean value of enzymatic activity from two independent experiments with at least three replicates. Vertical bars represent standard deviation. Means followed by the same letter are not different at judged by Duncan’s multiple range test at P < 0.0001. Details in measuring enzymatic activities are described in the text. F) Northern-blot analysis of fungal RNA purified from isolate Ef12 and Ef41 of Elsinoë fawcettii. RNA was denatured in a formaldehyde-containing gel, blotted to a nylon membrane, and hybridized to a DNA probe (probe 3) generated from EfPKS1 gene of E. fawcettii CAL WH-1 isolate as described in chapter 4. Gel stained with ethidium bromide indicates relative loading of the RNA samples. Sizes of hybridization bands are indicated in kilobase pairs.
148
Figure 6-3. Alleviation of symptom development by co-inoculation of two Elsinoë fawcettii isolates. Conidial suspensions (1 μL, 1 x 105 mL-1) of a non-pathogenic isolate (Ef41), two low/moderate-virulent isolates (Ef29 and Ef49), and a high-virulent isolate (Ef12) of Elsinoë fawcettii were placed alone or in combinations onto detached leaves of rough lemon (A), and grapefruit (B) (14 days after emergence). Inoculated leaves were incubated in a moist chamber. Formation of scab lesions was recorded 12 days post inoculation. The controls were inoculated with water only. Disease severity is rated on a scale, 0 for no lesion formation; 1, chlorotic reaction only, no scab pustules; 2, lesions with minor pustules; 3, scab pustules present, shower forming; 4, scab formed on all sites; and 5, lesions with severe pustules. % leaves with symptoms was calculated from over 100 leaves inoculated in three independent experiments.
149
Figure 6-4. Electrophoresis of the amplified internal transcribed spacer (ITS) rDNA fragments after cleaved with A) HaeIII; B) MspI; C) TaqαI on 2% agarose gels. The numbers of Elsinoë fawcettii isolates are marked upon the lanes. M1, the 123 DNA ladder; M2, 1 kb ladder (Promega). Isolate Ef41 showed the different patterns among all three restriction enzyme digestions compared to the remaining isolates.
150
Figure 6-5. Electrophoresis of the amplified partial β-tubulin genes (~500bp) digested with six different 4-bp recognition sequence restriction enzymes on 2% agarose gels. The numbers of Elsinoë fawcettii isolates are marked upon the lanes. M, the 100 bp DNA ladder. The pattern of isolate Ef41 differed from the HaeIII and TaqαI digestion patterns of the other two remaining isolates, Ef12 and Ef49.
151
Figure 6-6. Electrophoresis of the randomly amplified polymorphic DNA fragments (RAPD) on 2% agarose gels. The numbers of Elsinoë fawcettii isolates are marked upon the lanes. M, 1 kb ladder (Promega). 10-mer primers, OPX-7, OPX-13, or MtR 1 was used to randomly amplify DNA from the isolates. Isolate Ef41 showed the different patterns from the remaining isolates in all three amplifications.
152
Figure 6-7. Comparison of the internal transcribed spacer 1 (ITS 1) sequences between Elsinoë fawcettii Florida isolates and other Elsinoë spp. and other species belonging to the order of Loculoascomycetes via phylogenetic analysis. The phylogenetic tree was generated by using DS Gene v2.5 program with 100 bootstrap replicates. E. fawcettii Florida isolates Ef12, Ef29, Ef41, and Ef49 were sequenced in this study. Accession numbers for all sequences obtained from GenBank, original-collected host of Elsinoë spp, and location of Elsinoë spp. were indicated in parentheses.
153
APPENDIX A SUPPLEMENTAL DATA FOR CHAPTER TWO
Figure A-1. Spectrophotometric absorbance of elsinochromes (ESCs) treated with 3-(N-morpholino) propanesulfonic acid (MOPS) buffer (open bars), ESCs treated with nitrotetrazolium blue chloride (NBT) (hatched bars), or ESCs treated with both MOPS and NBT (closed bars) at 560 nm. Vertical bars represent standard deviation. Means followed by the same letter are not different at judged by Duncan’s multiple range test at P < 0.0001.
154
APPENDIX B SUPPLEMENTAL DATA FOR CHAPTER THREE
Table B-1. Effects of ions on ESC production on CM by E. fawcettii Treatment Concn
(mM) Mean colony dai. (mm) ± SEM
ESC (nmoles per plug), mean ± SEM
none - 10.31± 0.24 2.72 ± 0.32 CuCl2·2H2O 0.1 nd1 nd 1.0 9.34 ± 0.41 6.94 ± 0.36 10.0 nd nd FeCl3 0.1 10.22 ± 0.21 3.84 ± 0.22 0.2 10.97 ± 0.12 3.00 ± 1.24 0.5 10.97 ± 0.45 3.70 ± 1.52 1.0 9.72 ± 0.12 3.56 ± 1.08 2.0 10.19 ± 0.65 5.60 ± 0.70 10.0 nd nd KCl 50.0 nd nd 100.0 10.56 ± 0.24 3.08 ± 0.16 MgCl2·6H2O 50.0 nd nd 100.0 9.56 ± 0.60 2.78 ± 0.72 MnCl2·4H2O 0.2 10.31 ± 0.52 1.46 ± 0.56 1.0 9.81 ± 0.31 4.48 ± 0.56 5.0 9.81 ± 0.38 5.68 ± 1.00 10.0 10.50 ± 0.46 5.92 ± 0.18 100.0 nd nd NaCl 50.0 nd nd 100.0 10.44 ± 0.60 4.94 ± 0.22 ZnCl2 0.1 nd nd 1.0 11.00 ± 0.43 5.52 ± 0.38 10.0 nd nd
1nd, not determined
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APPENDIX C SUPPLEMENTAL DATA FOR CHAPTER FOUR
Table C-1. Sequences of primers Name Sequences efup 1 5’-GCACTCCTGACCCGATTGGA-3’ efup 5 5’-CCGATCTACGCTCCTTACCACGCTG-3’ efpks 1 5’-CTCCACGTGAAGCGGCACAGAC-3’ efpks 5 5’-GGATCAGTCTGTGCCGCTTCACGTGG-3’ efdown 5 5’-CGGTAGTTGTGCTGGATGCGACGAG-3’ efdown 8 5’-CCGAAACGCCCTTGGTTCAAAGATG-3’ ef down 10 5’-CATCATCGGCGGTTGGTCAGCAGG-3’
156
Figure C-1. Schematic describing the strategies to obtain full-length of EfPKS1. The amplified
DNA fragment (hatched bar, about 700 bp) by two degenerate oligonucleotides (LCKS1/LCKS2) was first used for extension of 5’ and 3’ franking region of EfPKS1 gene. Chromosome walking (CW) and inverse PCR (IP) were used to obtain full-length of EfPKS1. Arrowheads indicate relative positions of primers used for chromosome walking (efpks 1, efpks 5, and efdown 10) and inverse PCR (efup 1/efup 5 and efdown 5/efdown 8). Restriction enzyme sites used for inverse PCR were indicated. Drawing is not to scale.
157
APPENDIX D SUPPLEMENTAL DATA FOR CHAPTER SIX
Table D-1. Germination of Elsinoë fawcettii isolates on detached leaves of rough lemon and grapefruit
Isolate no. Pathogenicity1 Germination (% of conidia with germ tube/total conidia)2 Rough lemon Grapefruit 41 none 0 0 29 low 4 ± 0.3 2 ± 0.1 12 high 33 ± 4.3 23 ± 3.0
1Pathogenicity assays were conducted on detached leaves as described in Table 6-1. 2Germination was evident by forming germ tube. For each isolate, 100 conidia were examined and the data show the means and standard errors of three independent experiments.
158
Figure D-1. Elsinoë fawcettii hyphae observed using a light microscope at x 200 magnification.
Nonpathogenic isolate (Ef41), low virulence isolates (Ef10, Ef17, Ef29, and Ef49), and high virulence isolates (Ef12, Ef30, Ef37, and Ef48) of Elsinoë fawcettii were cultured on PDA under constant fluorescence light. Small pieces of young (4 day culture) and old (8 day culture) mycelia were removed from PDA, suspended in water and placed on slides for observation.
159
Figure D-2. Variation of fungal colony under a dissection microscope at x 25 magnification.
Non-pathogenic isolate (Ef41), low virulence isolates (Ef10, Ef17, Ef29, and Ef49), and high virulence isolates (Ef12, Ef30, Ef37, and Ef48) of Elsinoë fawcettii were cultured on PDA media under constant fluorescence light for 10 days.
160
EF12CGAGCTGTGACCTGTTCCAGAGCTTACACAGCACATCTTCGACCCCAGGAACATGATGGC EF41CGCGCCGTTAGC_GTGCCAGAACTTACCCAGCAAATCTTCGACCCGAGGAACATGATGGC AN__CGCGCTGTTTCC_GTTCCCGAGTTGACCCAGCAGATGTTCGACCCCAAGAACATGATGGC CB__CGTGCTGTCACC_GTTCCAGAGCTCACCCAGCAAATCTTCGACCCCAAGAACATGATGGC MG__CGCGCCGTCACC_GTCCCCGAGCTCACCCAGCAAATCTTCGACCCCAAGAACATGATGGC NC__CGTGCCGTCTCC_GTGCCCGAGTTGACCCAGCAGATGTTCGACCCCAAGAACATGATGGC NF__CGTGCTGTCTCC_GTTCCTGAGTTGACCCAGCAGATGTTCGACCCCAAGAACATGATGGC SS__CGTGCTGTTACT_GTTCCAGAGTTGACCCAACAAATGTATGATCCTAAGAACATGATGGC VD__CGTGCCGTCAGC_GTTCCTGAGCTCACCCAGCAGATGTTCGACCCCAAGAACATGATGGC EF12TGC_TTCCGACTTCCGCAACGGTCGTTACCTCACCTGCTCTGCCATCTT___________ EF41CGC_AGCTGACTTCCGCAACGGACGCTACCTCACCTGCTCTGCCATCTT___________ AN__TGC_CTCTGACTTCCGCAACGGCCGCTACCTCACCTGCTCCGCTATCTT___________ CB__CGCCAGC_GACTTCCGCAACGGCCGTTACCTCACTTGCTCGGCTATCTA___________ MG__CGCCAGC_GATTTCCGCAACGGTCGTTACCTCACCTGCTCCGCCATCTA___________ NC__TGC_TTCTGACTTCCGCAACGGTCGTTACCTCACCTGCTCTGCCATCTT___________ NF__TGC_TTCCGACTTCCGCAACGGACGTTACCTCACCTGCTCTGCCATTTT___________ SS__CGC_TTCCGATTTCCGTAACGGTCGTTACTTAACCTGCTCTGCTATCTTGTAAGTTTGCC VD__CGC_CTCTGACTTCCGTAACGGTCGCTACCTGACCTGCTCCGCCATCTTGTAAGCTCTAC _ EF12_________________________________________________________CCG EF41_________________________________________________________CCG AN___________________________________________________________CCG CB___________________________________________________________CCG MG___________________________________________________________CCG NC___________________________________________________________CCG NF___________________________________________________________CCG SS__ATATTACCCG_______________TCTGCAGCTCTATATATACTAATCGTGTGCAGCCG VD__CACCCCCCCTAAGCTCGTCCAAATTTGCTCTTTTCTAACAAAGTTTCCCTTCACCAGCCG EF12TGGCAAGGTCGCCATGAAGGAGGTTGAGGATCAGATCCGCAACGTCCAGACCAAGAACCC EF41TGGCAAGGTTTCCATGAAGGAGGTCGAGGACCAGATCCGTAACGTTCAGAACCGCAACCC AN__TGGAAAGGTCTCCATGAAGGAGGTTGAGGACCAGATGCGCAACATCCAGAGCAAGAACCA CB__TGGCAAGGTCTCCATGAAGGAAGTTGAGGACCAGATCCGCAACGTGCAGAACAAGAACAC MG__CGGAAAGGTGTCCATGAAGGAGGTCGAGGACCAGATCCGCAACGTGCAGAACAAGAACAC NC__TGGCAAGGTCTCCATGAAGGAGGTTGAGGACCAGATGCGCAACGTTCAGAACAAGAACTC NF__TGGTAAGGTTTCCATGAAGGAGGTCGAGGACCAGATGCGCAACATCCAGTCCAAGAACCA SS__TGGTAAGGTTTCCATTAAGGAGGTTGAGGACCAAATGCGCAATGTCCAAAACAAGAACTC VD__TGGCAAGGTTGCCATGAAGGAGGTCGAGGACCAGATGCGCAACGTCCAGAGCAAGAACTC Figure D-3. Alignment of nucleotide sequences of fungal partial β-tubulin genes. The % identity
between organisms were described in Table 6-2. Partial β-tubulin genes of Elsinoë fawcettii isolates, Ef12, and Ef41, were amplified by primer sets, Bt1F and Bt1R, and sequenced. Partial β-tubulin genes from other fungi were obtained from Genbank with accession numbers. AN, Aspergillus nidulans (XM_653694); CB, Cercospora beticola (AY856373); MG, Mycosphaerella graminicola (AJ310917); NC, Neurospora crassa (XM_952576); NF, Neosartorya fischeri (XM_001264677); SS, Sclerotinia sclerotiorum (AY12374); VD, Verticillium dahliae (DQ266135).
161
EF12CTCATACTTCGTCGAGTGGATCCCGAACAACGTCCAGACCGCCCTCTGCTCTATTCCCCC EF41TGCCTACTTCGTCGAGTGGATCCCCAACAACGTCCAGACCGCGCTGTGCTCAATCCCACC AN__GTCCTACTTCGTCGAGTGGATTCCCAACAACATCCAGACCGCTCTCTGCTCCATTCCTCC CB__TGCCTACTTCGTCGAGTGGATTCCAAACAACGTCCAGACCGCACTGTGCTCTATCCCACC MG__CGCATACTTCGTCGAGTGGATCCCGAACAACGTCCAGACCGCGCTGTGCTCCATTCCTCC NC__TTCCTACTTCGTCGAGTGGATCCCCAACAACGTCCAGACTGCCCTCTGCTCTATCCCTCC NF__GAGCTACTTCGTTGAGTGGATTCCCAACAACATCCAGACCGCTCTGTGCTCCATTCCCCC SS__TTCCTACTTCGTCGAGTGGATCCCTAACAATGTCCAAACCGCCCTTTGCTCCATTCCTCC VD__TTCGTACTTCGTTGAGTGGATCCCCAACAACGTCCAGACCGCCCTTTGCTCCATCCCTCC EF12ACGCGGCCTCAAGATGTCTTCCACCTTTGTCGGCAACTCCACCTCCATTCAGGAGCTCTT EF41AAAGGGCCTCAAGATGTCGTCGACTTTCGTCGGCAACTCGACTTCCATCCAGGAGCTCTT AN__CCGCGGCCTCAAGATGTCTTCCACCTTCATTGGAAACTCTACTTCCATCCAGGAGCTCTT CB__ACGCGGCCTCAAGATGTCTTCTACCTTCGTTGGAAACAGCACTTCGATCCAGGAGCTCTT MG__CCGTGGATTGAAGATGTCGTCCACCTTCGTCGGCAACTCCACCTCCATTCAGGAGCTCTT NC__CCGCGGTCTCAAGATGTCCTCCACCTTCGTCGGTAACTCCACCGCCATCCAGGAGCTCTT NF__CCGTGGCCTGAAGATGTCCTCCACCTTCATTGGTAACTCCACCTCCATCCAGGAGCTGTT SS__CCGTGGTCTCAAGATGTCCTCCACCTTCGTCGGTAACTCGGCCTCCATCCAAGAACTCTT VD__CCGTGGCCTCAAGATGTCCTCCACCTTCGTCGGTAACTCCACCGCCATCCAGGAGCTCTT EF12CAAGCGTGTTGGCGATCAGTTCACTGCTATGTTCCGTCGCAAGGCTTTCTTGCATTGGTA EF41CAAGCGTGTTGGCGACCAGTTCTCCGCTATGTTCCGTCGCAAGGCTTTCCTTCACTGGTA AN__CAAGCGTGTCGGTGACCAGTTCACTGCTATGTTCCGTCGCAAGGCTTTCTTGCATTGGTA CB__CAAGCGTGTCGGTGACCAGTTCACTGCCATGTTCAGGCGCAAGGCCTTCTTGCACTGGTA MG__TAAGCGTGTCGGTGACCAGTTCTCCGCTATGTTCAGGCGCAAGGCTTTCTTGCATTGGTA NC__CAAGCGTATCGGCGAGCAGTTCACTGCCATGTTCAGGCGCAAGGCTTTCTTGCATTGGTA NF__CAAGCGTGTCGGTGATCAGTTCACTGCTATGTTCCGTCGCAAGGCTTTCTTGCATTGGTA SS__CAAGCGTGTCGGTGATCAATTCACTGCTATGTTCAGAAGAAAGGCTTTCTTGCATTGGTA VD__CAAGCGTATCGGCGAGCAGTTCACTGCCATGTTCCGGCGCAAGGCTTTCCTTCACTGGTA EF12CACTGGTGAGGGCATGGACGAGATGGAGTTCACTGAGGCTGAGTTCAACATGAACGATCT EF41CACCAGCGAAGGTATGGACGAGATGGAGTTCACCGAAGCAGAGTTCAACATGAACGATCT AN__CACTGGTGAGGGTATGGACGAGATGGAGTTCACTGAGGCTGAGAGCAACATGAACGATCT CB__CACTGGCGAGGGTATGGACGAGATGGAGTTCACTGAGGCTGAGTCCAACATGAACGACTT MG__CACTGGCGAGGGCATGGATAAGATGGAGTTTACCGAGGCCGAGTCCAACATGAACGATTT NC__CACTGGTGAGGGTATGGACGAGATGGAGTTCACTGAGGCTGAGTCCAACATGAACGATCT NF__CACTGGCGAGGGTATGGACGAGATGGAGTTCACTGAGGCCGAGAGCAACATGAACGATCT SS__CACTGGCGAAGGTATGGACGAAATGGAGTTCACTGAGGCTGAGTCCAACATGAACGATTT VD__CACTGGTGAGGGTATGGACGAGATGGAGTTCACTGAGGCTGAGTTCAACATGAACGATCT EF12CGTC EF41CGTC AN__CGTC CB__GGTG MG__GGT NC__CGTC NF__GGTC SS__GGTC VD__CGTC Figure D-3. (Continued)
162
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BIOGRAPHICAL SKETCH
Hui-Ling Liao was born in Taiwan in 1975. Before attending the University of Florida for
pursuing Ph.D in August 2004, she completed her Bachelor of Science in plant pathology at
National Chung Hsing University in June 1998, and obtained a Master of Science in plant
pathology at National Taiwan University in June 2000. She joined a plant pathology laboratory
as a research assistant at National Chung Hsing University from 2000 to 2001. Later, she was a
teaching assistant in the department of biology in Tunghai University in Taiwan from 2001 to
2004.
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